Truncated and dispersed rpl2 and rps19 pseudogenes are co-transcribed with neighbouring downstream genes in wheat mitochondria.

The wheat mitochondrial genome contains only partial coding sequences for the L2 and S19 ribosomal proteins, unlike in rice or liverwort mitochondria, where these genes are functional and have a bacterial-type linkage. A single-copy stretch corresponding to the extreme 3' terminus of the wheat rpl2 gene is co-transcribed with the trans-splicing nad1 exon 4; and, at another unique location, the rps19 segment lacking the 5' coding region is co-transcribed with the downstream nad4L gene. In both cases, the 5' termini of these transcripts map to promoter consensus motifs acquired through genomic reorganization, enabling continued expression of essential downstream genes. In both wheat and rice, the rpl2 and rps19 genomic regions differ in their RNA profiles between germinating embryos and seedlings. The absence of intact rpl2 and rps19 genes in wheat mitochondria is consistent with their inactivation through DNA rearrangement/deletion after the successful transfer of functional copies to the nucleus.

The ins and outs of group II introns.

Group II introns have attracted considerable attention as ribozymes, mobile genetic elements and possible progenitors of nuclear spliceosomal introns. Major advances in understanding their catalytic structure and dispersal strategies have recently come from several model mitochondrial and bacterial self-splicing introns. In Nature, this family of introns shows wide variation in both features and behaviour, and this review includes a focus on the diversity of evolutionary pathways taken.

Variation in sequence and RNA editing within core domains of mitochondrial group II introns among plants.

The 3' regions of several group II introns within the mitochondrial genes nad1 and nad7 show unexpected sequence divergence among flowering plants, and the core domains 5 and 6 are predicted to have weaker helical structure than those in self-splicing group II introns. To assess whether RNA editing improves helical stability by the conversion of A-C mispairs to A-U pairs, we sequenced RT-PCR amplification products derived from excised intron RNAs or partially spliced precursors. Only in some cases was editing observed to strengthen the predicted helices. Moreover, the editing status within nad1 intron 1 and nad7 intron 4 was seen to differ among plant species, so that homologous intron sequences shared lower similarity at the RNA level than at the DNA level. Plant-specific variation was also seen in the length of the linker joining domains 5 and 6 of nad7 intron 3; it ranged from 4 nt in wheat to 11 nt in soybean, in contrast to the 2-4 nt length typical of classical group II introns. However, this intron is excised as a lariat structure with a domain 6 branchpoint adenosine. Our observations suggest that the core structures and sequences of these plant mitochondrial introns are subject to less stringent evolutionary constraints than conventional group II introns.

The S7 ribosomal protein gene is truncated and overlaps a cytochrome c biogenesis gene in pea mitochondria.

The pea mitochondrial genome contains a truncated rps7 gene lacking ca. 40 codons at its 5' terminus. This single-copy sequence is immediately downstream of and slightly overlapping an actively transcribed and edited reading frame of 744 bp (designated ccb248) homologous to the bacterial helC gene which encodes a subunit of the ABC-type heme transporter involved in cytochrome c biogenesis. This region of mitochondrial DNA appears recombinogenic, and the carboxy-termini of helC-type proteins are predicted to vary in sequence and length among plants. Sequences corresponding to the 5' coding region of rps7 were not detected elsewhere in the pea mitochondrial genome using wheat rps7 probes, and only a very short internal rps7 segment was observed in soybean mitochondrial DNA. The presence of rps7-homologous sequences in the nuclear genomes of pea and soybean is consistent with the recent transfer of a functional mitochondrial rps7 gene to the nucleus in certain plant lineages.

RNA editing status of nad7 intron domains in wheat mitochondria.

The most highly conserved structures of group II introns are the helical domains V and VI near the 3'splice site. Within this region of each of the four introns in the wheat mitochondrial nad7 gene encoding NADH dehydrogenase subunit 7, there are A-C mispairs. To determine whether C-to-U type RNA editing restores conventional A-U pairing, we sequenced RT-PCR products from partially-spliced nad7 template RNA and gel-fractionated, excised intron RNA. We examined transcripts from germinating wheat embryos and seedlings because these two stages of development show pronounced differences in steady state levels of nad7 intronic RNAs. We observed editing at only two of the six predicted sites, and they were located at homologous positions within domain V of the third and fourth introns. A third site was found to be edited within the unmodelled domain VI loop of the fourth intron. Similar patterns of RNA editing were seen in wheat embryos and seedlings. These observations, and the presence of other non-conventional base pairs particularly within domain V of plant mitochondrial introns, indicate weaker helical core structure than in ribozymic group II introns. Moreover, the incompleteness or absence of editing in wheat nad7 excised intron RNA suggests that, although editing may contribute to splicing efficiency, it is not essential for splicing.

The NADH dehydrogenase subunit 7 gene is interrupted by four group II introns in the wheat mitochondrial genome.

We have characterized a wheat mitochondrial gene, designated nad7, capable of encoding a 394-amino acid subunit of the respiratory chain NADH dehydrogenase complex. It contains four introns possessing group II features and their positions differ from those in both the liverwort mitochondrial nad7 pseudogene and the nuclear gene encoding the homologous 49 kDa subunit of complex I in Neurospora. The derived amino acid sequence of the wheat nad7 gene is strongly conserved relative to its nuclear or organellar counterparts in other organisms. C-to-U type RNA editing, which is observed at 32 positions within the coding region of wheat nad7 transcripts, strengthens protein sequence similarity. RNA editing is also predicted to improve base-pairing within the domain V/VI regions of all four introns.

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.

Characterization of the S7 ribosomal protein gene in wheat mitochondria.

By screening a wheat mitoplast cDNA bank, we have identified an open reading frame of 444 bp that has a derived amino acid sequence homologous to bacterial-type S7 ribosomal proteins. This gene, designated rps7, is located upstream of one of two 26S rRNA gene copies in the wheat mitochondrial genome and is expressed as an abundant mRNA of approximately 0.7 kb. Its 5' terminus maps to the end of an 80 bp element that is closely related to sequences preceding the wheat coxII, orf25 and atp6 genes. Southern hybridization analysis indicates that rps7-homologous sequences are present in the mitochondria of rice and pea, but not soybean.

Trans-splicing of pre-mRNA in plants, animals, and protists.

Messenger RNA maturation in eukaryotes typically involves the removal of introns from long precursor molecules. An unusual form of RNA splicing in which separate precursor transcripts contribute sequences to the mature mRNA through intermolecular reactions has now been documented in a number of diverse organisms. In this review, the phenomenon of pre-mRNA trans-splicing has been divided into two categories. The "spliced leader" type, found in protozoans such as trypanosomes and lower invertebrates such as nematodes, results in the addition of a short, capped 5' noncoding sequence to the mRNA. The "discontinuous group II intron" form of trans-splicing, found in plant/algal chloroplasts and plant mitochondria, involves the joining of independently transcribed coding sequences, presumably through interactions between "intronic" RNA pieces. Both categories of trans-splicing are mechanistically similar to conventional nuclear pre-mRNA cis-splicing; potential evolutionary relationships are discussed.

Inheritance of mitochondrial DNA in the conifer Larix.

Restriction fragment length polymorphisms between Larix leptolepis and Larix decidua were identified in heterologous hybridization experiments, using wheat mitochondrial DNA probes specific for atp9, coxI, nad3/rps12, and orf25. Analysis of eight individuals of each reciprocal hybrid of these two species revealed that mitochondrial DNA was maternally inherited. Furthermore, sequences homologous to wheat orf25 were also identified in Larix gmelini, Larix siberica, Larix olgensis, and Larix laricina, as well as Ginkgo biloba, Picea mariana, Picea glauca and Pinus contorta.

The mitochondrial genome: so simple yet so complex.

Mitochondria possess a small set of genes that are essential for respiratory function. This review highlights recent advances in our understanding of mitochondrial gene organization and expression. These studies illustrate a remarkable diversity among eukaryotic lineages and an impressive complexity of events needed to achieve nuclear-mitochondrial harmony.

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.

Characterization of the wheat mitochondrial orf25 gene.

The wheat mitochondrial orf25 nucleotide sequence of 576 bp has been determined. Its derived protein sequence shares 88% and 75% amino acid identity with those of maize and tobacco mitochondria, respectively. The wheat and tobacco orf25 sequences lack four inserts, of 6 bp to 36 bp, that are present in the maize homologue. The wheat orf25 gene is actively transcribed and is preceded by a regulatory sequence block very similar to those located upstream of the wheat coxII and atp6 genes. Our observations support the view that orf25 sequences encode a functional polypeptide in plant mitochondria.

Sequence analysis of the wheat mitochondrial atp6 gene reveals a fused upstream reading frame and markedly divergent N termini among plant ATP6 proteins.

The nucleotide sequence of the wheat mitochondrial gene for subunit 6 (atp6) of the F1F0 ATPase complex has been determined. Unlike bacterial, chloroplast or animal/fungal mitochondrial atp6 counterparts, which encode proteins of about 230-270 amino acids, the wheat mitochondrial atp6 homologue comprises the latter part of an open reading frame (ORF) of 386 codons. The ATP6 protein may therefore by synthesized with a long N-terminal presequence. This is supported by the finding that the ORF is preceded by a conserved sequence block closely related to ones preceding several other actively transcribed wheat mitochondrial protein-coding genes. The fused upstream ORF is similar in length, but unrelated in sequence, to those preceding the maize and tobacco mitochondrial atp6 genes. In wheat, the atp6 gene is located on a recombinationally active repeated DNA element, whose length of 1.4 kb corresponds approximately to that of the atp6 mRNA. A comparison of the wheat and maize ATP6 sequences reveals unexpectedly high divergence in the region corresponding to the mature N-terminal domain and may reflect mitochondrial DNA rearrangements during atp6 gene evolution in monocotyledonous plants.

Genes for tRNA(Asp), tRNA (Pro), tRNA (Tyr) and two tRNAs (Ser) in wheat mitochondrial DNA.

We have begun a systematic search for potential tRNA genes in wheat mtDNA, and present here the sequences of regions of the wheat mitochondrial genome that encode genes for tRNA(Asp) (anticodon GUC), tRNA(Pro) (UGG), tRNA(Tyr) (GUA), and two tRNAs(Ser) (UGA and GCU). These genes are all solitary, not immediately adjacent to other tRNA or known protein coding genes. Each of the encoded tRNAs can assume a secondary structure that conforms to the standard cloverleaf model, and that displays none of the structural aberrations peculiar to some of the corresponding mitochondrial tRNAs from other eukaryotes. The wheat mitochondrial tRNA sequences are, on average, substantially more similar to their eubacterial and chloroplast counterparts than to their homologues in fungal and animal mitochondria. However, an analysis of regions ∼ 150 nucleotides upstream and ∼ 100 nucleotides downstream of the tRNA coding regions has revealed no obvious conserved sequences that resemble the promoter and terminator motifs that regulate the expression of eubacterial and some chloroplast tRNA genes. When restriction digests of wheat mtDNA are probed with (32)P-labelled wheat mitochondrial tRNAs, <20 hybridizing bands are detected, whether enzymes with 4 bp or 6 bp recognition sites are used. This suggests that the wheat mitochondrial genome, despite its large size, may carry a relatively small number of tRNA genes.

The mitochondrial S13 ribosomal protein gene is silent in wheat embryos and seedlings.

The sequence of a wheat mitochondrial reading frame encoding a protein homologous to the E. coli S13 small subunit ribosomal protein has been determined. The gene is located immediately downstream of a 1.4 kb recombinationally-active repeat element that contains the ATPase subunit 6 gene. The coding regions of the two genes are separated by only 153 bp, the shortest distance yet observed between protein-coding genes in plant mitochondria. However, their transcript profiles differ markedly. The ATPase 6 gene displays a single, prominent mRNA of approximately 1.4 kb, whereas the S13 gene shows no stable transcript as judged by Northern blot analysis of wheat mitochondrial RNA isolated from different developmental stages. A short segment of the 26S rRNA gene is located downstream of the S13 gene and its presence illustrates the frequent DNA duplication/rearrangements found in wheat mitochondria.

Excised group II introns in yeast mitochondria are lariats and can be formed by self-splicing in vitro.

Excised group II introns in yeast mitochondria appear as covalently closed circles under the electron microscope. We show that these circular molecules are branched and resemble the lariats arising through splicing of nuclear pre-mRNAs in yeast and higher eukaryotes. One member of this intron class (aI5c in the gene for cytochrome c oxidase subunit I) is capable of self-splicing in vitro, giving correct exon-exon ligation and resulting in the appearance of both linear and lariat forms of the excised intron. Nuclease digestion of the latter molecules reveals the presence of a complex oligonucleotide with the probable structure AGU, which thus resembles the branch point formed in the spliceosome-dependent reactions undergone by nuclear pre-mRNAs. Unlike group I introns, this group II intron is not demonstrably dependent on GTP for self-splicing and circularization of the isolated, linear intron is not observed. A model accounting for these observations is presented.