RNA editing of sorghum mitochondrial atp6 transcripts changes 15 amino acids and generates a carboxy-terminus identical to yeast

A Systematic Review and Developmental Perspective on Origin of CMS Genes in Crops

Cytoplasmic male sterility (CMS) arises from the incompatibility between the nucleus and cytoplasm as typical representatives of the chimeric structures in the mitochondrial genome (mitogenome), which has been extensively applied for hybrid seed production in various crops. The frequent occurrence of chimeric mitochondrial genes leading to CMS is consistent with the mitochondrial DNA (mtDNA) evolution. The sequence conservation resulting from faithfully maternal inheritance and the chimeric structure caused by frequent sequence recombination have been defined as two major features of the mitogenome. However, when and how these chimeric mitochondrial genes appear in the context of the highly conserved reproduction of mitochondria is an enigma. This review, therefore, presents the critical view of the research on CMS in plants to elucidate the mechanisms of this phenomenon. Generally, distant hybridization is the main mechanism to generate an original CMS source in natural populations and in breeding. Mitochondria and mitogenomes show pleomorphic and dynamic changes at key stages of the life cycle. The promitochondria in dry seeds develop into fully functioning mitochondria during seed imbibition, followed by massive mitochondria or mitogenome fusion and fission in the germination stage along with changes in the mtDNA structure and quantity. The mitogenome stability is controlled by nuclear loci, such as the nuclear gene Msh1. Its suppression leads to the rearrangement of mtDNA and the production of heritable CMS genes. An abundant recombination of mtDNA is also often found in distant hybrids and somatic/cybrid hybrids. Since mtDNA recombination is ubiquitous in distant hybridization, we put forward a hypothesis that the original CMS genes originated from mtDNA recombination during the germination of the hybrid seeds produced from distant hybridizations to solve the nucleo-cytoplasmic incompatibility resulting from the allogenic nuclear genome during seed germination.

RNA editing: only eleven sites are present in the Physcomitrella patens mitochondrial transcriptome and a universal nomenclature proposal

RNA editing in mitochondria and chloroplasts of land plants alters the coding content of transcripts through site-specific exchanges of cytidines into uridines and vice versa. The abundance of RNA editing in model plant species such as rice or Arabidopsis with some 500 affected sites in their organelle transcripts hinders straightforward approaches to elucidate its mechanisms. The moss Physcomitrella patens is increasingly being appreciated as an alternative plant model system, enhanced by the recent availability of its complete chloroplast, mitochondrial, and nuclear genome sequences. We here report the transcriptomic analysis of Physcomitrella mitochondrial mRNAs as a prerequisite for future studies of mitochondrial RNA editing in this moss. We find a strikingly low frequency of RNA editing affecting only eleven, albeit highly important, sites of C-to-U nucleotide modification in only nine mitochondrial genes. Partial editing was seen for two of these sites but no evidence for any silent editing sites (leaving the identity of the encoded amino acid unchanged) as commonly observed in vascular plants was found in Physcomitrella, indicating a compact and efficient organization of the editing machinery. Furthermore, we here wish to propose a unifying nomenclature to clearly identify and designate RNA editing positions and to facilitate future communication and database annotation.

Did RNA editing in plant organellar genomes originate under natural selection or through genetic drift?

Background

The C↔U substitution types of RNA editing have been observed frequently in organellar genomes of land plants. Although various attempts have been made to explain why such a seemingly inefficient genetic mechanism would have evolved, no satisfactory explanation exists in our view. In this study, we examined editing patterns in chloroplast genomes of the hornwort Anthoceros formosae and the fern Adiantum capillus-veneris and in mitochondrial genomes of the angiosperms Arabidopsis thaliana, Beta vulgaris and Oryza sativa, to gain an understanding of the question of how RNA editing originated.

Results

We found that 1) most editing sites were distributed at the 2^nd and 1^st codon positions, 2) editing affected codons that resulted in larger hydrophobicity and molecular size changes much more frequently than those with little change involved, 3) editing uniformly increased protein hydrophobicity, 4) editing occurred more frequently in ancestrally T-rich sequences, which were more abundant in genes encoding membrane-bound proteins with many hydrophobic amino acids than in genes encoding soluble proteins, and 5) editing occurred most often in genes found to be under strong selective constraint.

Conclusion

These analyses show that editing mostly affects functionally important and evolutionarily conserved codon positions, codons and genes encoding membrane-bound proteins. In particular, abundance of RNA editing in plant organellar genomes may be associated with disproportionately large percentages of genes in these two genomes that encode membrane-bound proteins, which are rich in hydrophobic amino acids and selectively constrained. These data support a hypothesis that natural selection imposed by protein functional constraints has contributed to selective fixation of certain editing sites and maintenance of the editing activity in plant organelles over a period of more than four hundred millions years. The retention of genes encoding RNA editing activity may be driven by forces that shape nucleotide composition equilibrium in two organellar genomes of these plants. Nevertheless, the causes of lineage-specific occurrence of a large portion of RNA editing sites remain to be determined.

Reviewers

This article was reviewed by Michael Gray (nominated by Laurence Hurst), Kirsten Krause (nominated by Martin Lercher), and Jeffery Mower (nominated by David Ardell).

Transcript end mapping and analysis of RNA editing in plant mitochondria

Mitochondria are genetic compartments with their own enzymatic equipment for maintenance and expression of their genetic information. As in all genetic systems, gene expression has to be regulated, and in mitochondria this also has to be coordinated with the expression of nuclear-encoded mitochondrial proteins. Presently, there is virtually no information available about the mechanistic details and the enzymes involved in these processes. There is still much to be learned about how plant mitochondrial gene expression is managed and to what extent the contribution of transcription initiation and posttranscriptional processes, respectively, contribute to this control. As one prerequisite for better understanding of the mechanisms and regulatory controls, more fundamental data on mitochondrial transcription initiation and posttranscriptional RNA processing are necessary. As part of the essential methodology, we present methods for the analysis of the 5' and 3' extremities of mitochondrial transcripts and the identification of transcription initiation sites. An in organello system is described for the functional investigation of ribonucleic acid editing in plant mitochondria.

Patterns of partial RNA editing in mitochondrial genes of Beta vulgaris

RNA editing is a process that modifies the information in transcripts of almost all angiosperm mitochondrial protein-coding genes. In order to determine the frequency and distribution of mitochondrial RNA editing in Beta vulgaris, cDNAs were sequenced and compared to the published genome sequence. 357 C to U conversions were identified across the 31 known protein genes and pseudogenes in Beta, the fewest so far for a plant mitochondrial genome. Editing patterns in the putative gene orf518 indicate that it is most likely a functional ccmC homolog, indicating that patterns of editing can be a useful determinant of gene functionality. orf518 also contains a triplicated repeat region whose members are nearly identical yet differentially edited, most likely due to differences in the sequence context of the editing sites. In addition, we show that partial editing in Beta is common at silent editing sites but rare at nonsilent editing sites, extending previous observations to a complete plant mitochondrial genome. Finally, the degree of partial editing observed for certain genes was dependent on the choice of primers used, demonstrating that care must be taken when designing primers for use in editing studies.

The organization of mitochondrial atp6 gene region in male fertile and CMS lines of pepper (Capsicum annuum L.)

The mitochondrial atp6 gene in male fertile (N) and CMS (S) pepper has previously been compared and was found to be present in two copies (Kim et al. in J Kor Soc Hort Sci 42:121-127 2001). In the current study, these atp6 copies were amplified by an inverse PCR technique, and the coding region as well as the 5' and 3' flanking regions were sequenced. The atp6 copies in CMS pepper were detected as one intact gene and one pseudogene, truncated at the 3' coding region. When the atp6 genes in pepper were compared to other plant species, pepper, potato, and petunia all possessed a sequence of 12 identical amino acids at the 3' extended region, which was considered a hallmark of the Solanaceae family. Northern blot analysis showed differences in mRNA band patterns between CMS and restorer lines, indicating that atp6 gene is one of the candidates for CMS in pepper.

Mitochondrial electroporation and in organello RNA editing of chimeric atp6 transcripts

The Sorghum bicolor atp6-1 gene and chimeric atp6 genes with additional maize sequences were introduced into isolated maize mitochondria via electroporation. Transcripts isolated after in vitro incubation of the transformed organelles were then analysed for RNA editing. Transcripts of the S. bicolor atp6-1 gene, and the RNAs obtained from most of chimeric sorghum-maize atp6 gene constructs tested, were not edited. However, the transcript of one engineered chimeric gene comprising the 5'untranslated sequence and a segment of the N-terminal ORF of the maize atp6 combined with the sorghum atp6 core ORF and 3'untranslated sequence was found to be partially edited. We were able to exclude low RNA stability or insufficient editing capacity as the reason for failure to edit in the other instances. Instead, the data indicate that the maize sequence in the edited fusion transcript provides a structural motif or binding site for a transcript-specific editing factor.

The pea mitochondrial atp6: RNA editing and similarity of presequences in the Vicieae tribe

The atp6 gene has been identified as a single-copy sequence in the mitochondrial genome of the pea. An unexpected finding concerns the atp6 5' extension which is known to be poorly conserved at the sequence level, even between closely related plant species. We have shown that the presequences of ATP6 from the pea and other species belonging to the Vicieae tribe of Fabaceae (broad bean, hairy vetch) share a sequence similarity which extends to long 5' untranslated transcript termini. The reason for the observed conservation is not clear but may simply reflect the close phylogenetic relationship of species from the Vicieae tribe. The result of editing analysis indicates the occurrence of fully and partially edited transcripts of atp6 in the pea mitochondria. The majority of the editing sites are targeted to the last transmembrane domain of the pea ATP6, important in proton translocation and interactions with other subunits of ATP synthase.

The fertility restorer genes X and T alter the transcripts of a novel mitochondrial gene implicated in CMS1 in chives (Allium schoenoprasum L.)

A chimeric mitochondrial gene configuration, mainly derived from sequences associated with the essential genes atp9 and atp6, was isolated from the sterility-inducing cytoplasm of the CMS1 system in chives (Allium schoenoprasum L.). This sequence is not found in four other cytoplasm types from chives; however, two copies are present in the mitochondrial DNA of CMS1-inducing cytoplasm, whose 5'-sequences are homologous to those of the atp9 gene. We provide evidence to show that one of the two CMS1-specific copies is actively transcribed, and two transcripts which terminate at the same position but differ in their 5'initiation sites were localized using the RACE technique. These transcripts of 942 and 961 nt, respectively, were confirmed to be the major products of this gene in CMS1 plants by Northern hybridization. However, smaller transcripts were found to accumulate in plants in which fertility had been restored. Restoration of fertility was induced either by the gene X, or the gene T at high temperatures. In (S1) X. genotypes a transcript with an estimated size of 440 nt was detected in all tissues examined. An additional hybridization signal with an estimated size of approximately 850 nt is expressed in temperature-sensitive plants [(S1) xxT.], and the intensity of a minor 350-nt transcript is enhanced. These latter alterations, conditioned by the gene T, occur independently of the growth temperature, but are limited to the flowers; they were not observed in leaves. The CMS1 transcripts are edited at seven positions and contain an ORF with a maximum coding capacity of 780 nt (containing the start codon derived from the atp9 gene in-frame). Use of the third in-frame start codon would result in the synthesis of a protein of a size very close to that of a previously described CMS1-specific protein, which has an apparent molecular weight of 18 kDa. The coding sequence that begins at this third in-frame start codon is also present in the sterility-inducing cytoplasms (S) and (T) in the onion, and absent in (N) cytoplasm.

Electroporation of isolated higher-plant mitochondria: transcripts of an introduced cox2 gene, but not an atp6 gene, are edited in organello

To facilitate the analysis of RNA processing in plant mitochondria, a method was established for introducing foreign DNA into mitochondria isolated from maize and sorghum. This method permits the uptake of DNA of up to 11 kb into the mitochondrial matrix. In vitro incubation of maize mitochondria in a specific buffer system was found to permit splicing and editing of newly synthesized RNAs for a period of at least 7 h. This was shown both for transcripts of endogenous mitochondrial genes (atp6, cox2) and for transcripts derived from an introduced Arabidopsis thaliana cox2 gene. In contrast, when a Sorghum bicolor atp6 gene was introduced into isolated maize mitochondria, the gene was transcribed, but the RNA was not edited, although all the editing sites in maize and sorghum atp6 RNA are identical. This may indicate the presence of transcript-specific cis -acting regions in the up- or downstream untranslated sequences of the mRNA. The system described here should allow further dissection of the mechanism of RNA editing in plant mitochondria.

Cell type-specific loss of atp6 RNA editing in cytoplasmic male sterile Sorghum bicolor

RNA editing and cytoplasmic male sterility are two important phenomena in higher plant mitochondria. To determine whether correlations might exist between the two, RNA editing in different tissues of Sorghum bicolor was compared employing reverse transcription-PCR and subsequent sequence analysis. In etiolated shoots, RNA editing of transcripts of plant mitochondrial atp6, atp9, nad3, nad4, and rps12 genes was identical among fertile or cytoplasmic male sterile plants. We then established a protocol for mitochondrial RNA isolation from plant anthers and pollen to include in these studies. Whereas RNA editing of atp9, nad3, nad4, and rps12 transcripts in anthers was similar to etiolated shoots, mitochondrial atp6 RNA editing was strongly reduced in anthers of the A3Tx398 male sterile line of S. bicolor. atp6 transcripts of wheat and selected plastid transcripts in S. bicolor showed normal RNA editing, indicating that loss of atp6 RNA editing is specific for cytoplasmic male sterility S. bicolor mitochondria. Restoration of fertility in F1 and F2 lines correlated with an increase in RNA editing of atp6 transcripts. Our data suggest that loss of atp6 RNA editing contributes to or causes cytoplasmic male sterility in S. bicolor. Further analysis of the mechanism of cell type-specific loss of atp6 RNA editing activity may advance our understanding of the mechanism of RNA editing.

Involvement of 5' flanking sequence for specifying RNA editing sites in plant mitochondria

Unsuccessful insertion of foreign DNA into plant mitochondrial genomes has hindered scientific evaluation of cis-elements needed for RNA editing. Both a normal atp6 gene and a chimeric atp6 sequence are present in rice mitochondria. The chimeric atp6 contains one-half of the normal atp6 sequence in its 5' portion and an unknown sequence in its downstream portion. The C-nucleotide at position 511, located just upstream of the unknown sequence recombined in the chimeric atp6 sequence, is edited, as are other possible editing sites upstream from position 511. We report here that the 5' sequence adjacent to the editing site of atp6 contains cis-information required for RNA editing and that the 3' sequence flanking the editing site provides little contribution to editing-site recognition.

Universality of mitochondrial RNA editing in cytochrome-c oxidase subunit I (coxI) among the land plants

Plant mitochondrial pre-mRNAs often undergo C-to-U conversions, a phenomenon termed RNA editing. The molecular source of specificity and phylogenetic depth of the editing machinery remain to be determined. We amplified coxI gene fragments via the polymerase chain reaction from a diversity of taxa within the land plants, and sequenced each. Alignment and comparison of 25 homologous coxI gene sequences with those from plant species having known RNA editing sites which restore amino acid sequence consensus was used to infer sites of C-to-U conversions. Our results, derived using the comparative approach, imply that the plant mitochondrial editing machinery extends throughout vascular plant phylogeny, and also that this phenomenon is present in every major branch of the (non-vascular) Bryophyta: liverworts (Hepaticae), hornworts (Anthocerotae), and mosses (Musci). These results have important consequences for our thoughts on the evolutionary history of the plant RNA editing process, as they imply that editing is older than was previously believed.

Characterization of the radish mitochondrial nad3/rps12 locus: analysis of recombination repeats and RNA editing

In order to further investigate sequences that are responsible for low-frequency recombination in plant mitochondrial DNAs and RNA editing in radish mitochondria, the nad3/rps12 locus has been isolated and characterized from a normal cultivar of radish and the male-sterile Ogura cytoplasm. A repeated sequence that has been implicated in other radish mitochondrial DNA rearrangements was identified at the breakpoint between the two loci indicating that it was also involved in the nad3/rps12 rearrangement. Similar to some other radish mitochondrial genes, nad3/rps12 genomic sequences already contain several, but not all, of the bases that are typically edited in plant mitochondrial nad3 and rps12 genes. Analysis of nad3/rps12 cDNAs indicated that the mRNAs are not edited. One partially edited transcript was identified out of the twenty two that were examined. This finding, along with the observation that nad3/rps12 RNAs are present at very low levels, raises the possibility that radish mitochondria may not encode functional copies of these genes. Consistent with this hypothesis, DNA-blot analysis detects nad3/rps12 sequences in the nucleus.

Developmental- and tissue-specificity of RNA editing in mitochondria of suspension-cultured maize cells and seedlings

C to U editing of apt9, nad3, and cox2 mRNAs was investigated in maize seedlings at various developmental stages as well as in suspension-cultured cells. Heterogeneity of mRNAs that result from incomplete editing was analyzed for each gene and from five tissues or developmental conditions. The editing status of approximately 30 cDNA clones was determined by digestion with a restriction enzyme that discriminates between unedited and edited DNA sequences. The atp9 and spliced cox2 cDNAs were essentially completely edited in all samples examined. Analysis of three editing sites of nad3 cDNAs indicated that incompletely edited cDNAs were detected in all tissues and treatments with a temporal increase in the overall editing status, from 50% at 3 days to about 75% at 7 days. These results indicate that incompletely edited mRNAs are prevalent for some plant mitochondrial genes, and can change with developmental or growth conditions.

Protein polymorphism generated by differential RNA editing of a plant mitochondrial rps12 gene

The rps12 gene transcripts encoding mitochondrial ribosomal protein S12 are partially edited in petunia mitochondria. Different petunia lines were found vary in the extent of rps12 transcript editing. To test whether multiple forms of RPS12 proteins are produced in petunia mitochondria as a result of partial editing, we probed mitochondrial proteins with specific antibodies against edited and unedited forms of a 13-amino-acid RPS12 peptide spanning two amino acids affected by RNA editing. Both antibodies reacted with mitochondrial proteins at the expected size for RPS12 proteins. The amounts of unedited RPS12 protein in different petunia lines correlate with the abundance of unedited transcripts in these plants. Unedited rps12 translation products are also detected in other plant species, indicating that polymorphism in mitochondrial rps12 expression is widespread. Moreover, we show that RPS12 proteins recognized by both edited-specific and unedited-specific antibodies are present in a petunia mitochondrial ribosome fraction. These results demonstrate that partially edited transcripts can be translated and that the protein product can accumulate to detectable levels. Therefore, genes exhibiting incompletely edited transcripts can encode more than one gene product in plant mitochondria.

Sorghum mitochondrial orf25 and a related chimeric configuration of a male-sterile cytoplasm

We describe fundamental characteristics of sorghum mitochondrial orf25, urf209, and a related chimeric configuration, orf265/130, which is restricted to the IS1112C source of cytoplasmic male sterility in sorghum. Transcripts of urf209 are edited at ten nucleotides, resulting in nine amino-acid changes predicted from genomic sequences. The cDNA-predicted polypeptide product is 23.6 kDa, while Western blot analyses identify a product of 20k Da. Transcription of urf209 is characterized by one or two transcripts, dependent on nuclear background, but this difference is not related to male fertility status. The orf265/130 chimeric region includes 288 bp 95% identical to sequences 5' to maize T-cytoplasm T-urf13 and atp6, which includes a common transcription initiation site, and terminates with a recombinational event involving urf209. The urf209 similarity extends 189 bp, followed by sequences duplicated 5' to sorghum atp6-2. Sequences immediately 3' to the atp6-2 similarity include a second in-frame start codon, defining orf130. Structural features 5' to orf130 are shared with motifs found 5' to several translated mitochondrial open reading frames. The orf265/orf130 configuration is uniquely transcribed, and transcripts of orf130 exhibit one silent RNA editing event. Transcription in somatic cells is not altered by male fertility status.

Creation of an initiation codon by RNA editing in the coxI transcript from tomato mitochondria

Nucleotide-sequence analysis showed that the gene for cytochrome oxidase subunit I (coxI) from tomato mitochondrial DNA has an ACG codon at a conserved position corresponding to an ATG initiation codon in other higher-plant coxI genes. cDNA-sequence analysis of the coxI transcripts showed that 15 positions in the genomic DNA were converted from C to U in the transcripts by RNA editing. One of the editing events is observed at the indicated ACG codon, producing an ATG initiation codon. The nucleotide sequences of 37 cDNA clones showed that the initiation codon was created in 32 out of the 37 clones, while nucleotide positions 254 and 11 were edited in 37 and 34 of the 37 clones examined, respectively, suggesting that creation of the initiation codon is a post-transcriptional event. The BamHI site at nucleotide position 757-762 within the coxI genomic DNA was altered in all 97 cDNA clones examined, demonstrating that RNA editing at this site in the transcripts is very common. RNA editing takes place to a lesser extent at the initiation codon, compared with editing at internal position 254. This indicates that editing is either a random process or that it involves a mechanism favoring less RNA editing in the initiation codon than in internal sites.

Analysis of silent RNA editing sites in atp6 transcripts of Sorghum bicolor

We have observed numerous examples of silent or rare non-silent editing sites in the amino-extension and part of the conserved core of mitochondrial atp6 transcripts of Sorghum. In this region of the 1.4-kb atp6-2 mRNA (position 300 to 550) two editing sites, which alter the amino-acid sequence and occur in all cDNAs analysed, were already known, while nine others were found which are silent or occur in a few mRNAs only. Many aspects of RNA editing in the mitochondria of higher plants are still unknown. This includes the influence of genomic background or silent RNA editing. We were interested in the influence of nuclear and mitochondrial backgrounds on RNA editing. Previous preliminary results indicated the possibility of line-specific editing at silent sites. However, a more comprehensive approach gave no consistent evidence for such editing. These results are discussed with respect to their potential impact on the evolution of mitochondrial genes.

A leucine motif in the amino acid sequence of subunit 9 of the mitochondrial ATPase, and other hydrophobic membrane proteins, that is highly conserved by editing

Subunit 9 of the mitochondrial ATPase, but also other hydrophobic mitochondrially encoded proteins, contains a high frequency of the leucine motif, -Leu-X9-Leu-, which is highly conserved through RNA editing. The leucine motif may provide specific recognition sites between membrane-spanning domains of the F0-ATPase and between other hydrophobic subunits during the assembly of multienzyme complexes in the inner mitochondrial membrane.

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.

Differential screening of mitochondrial cDNA libraries from male-fertile and cytoplasmic male-sterile sugar-beet reveals genome rearrangements at atp6 and atpA loci

As part of a strategy to define differences in genome organization and expression between cytoplasmic male-sterile (CMS) and male-fertile (MF) sugar-beet mitochondria, cDNA libraries from both mitochondrial genotypes were constructed. Preliminary screening with ribosomal RNA gene probes identified candidate cDNA clones corresponding to structural genes. In addition, reciprocal hybridization experiments were performed using labelled first-strand cDNA to identify uniquely transcribed sequences. One cDNA clone (pYC700) is unique to CMS mitochondria and is located upstream of the F0F1-ATPase subunit 6 gene (atp6). Another cDNA clone (pYC130), when used as a probe in northern hybridization analysis, revealed novel transcript profiles in CMS sugar-beet mitochondria. Sequence analysis of this cDNA showed strong homology with the F0F1-ATPase subunit alpha (atpA) coding sequences from several higher plants. The atp6 and atpA loci from each genotype were cloned and the genomic organization, DNA sequence and transcription of each locus was studied. Differences in the transcript profiles of each gene are a consequence of genomic rearrangements 5' to the coding sequence.

Subunit 6 of the Fo-ATP synthase complex from cytoplasmic male-sterile radish: RNA editing and NH2-terminal protein sequencing

RNA editing and NH2-terminal processing of subunit 6 (atp6) of the mitochondrial Fo-ATPase complex has been investigated for the normal (fertile) and Ogura (male-sterile) radish cytoplasms to determine if previously identified differences between the Ogura atp6 locus and its normal radish counterpart are associated with cytoplasmic male sterility. Analysis of cDNA clones from five different sterile and fertile radish lines identified one C-to-U transition, which results in the replacement of a proline with a serine, in several of the lines. No editing of atp6 transcripts was observed in two lines, Scarlet Knight (normal radish) and sterile CrGC15 (Ogura radish). This is the first example of a naturally occurring plant mitochondrial gene that is not edited. The Ogura atp6 polypeptide is synthesized with a predicted NH2-terminal extension of 174 amino acids in contrast to the nine amino acid extension found in normal radish. In spite of the lack of similarity between the two extensions, NH2-terminal sequence analysis indicates that both polypeptides are processed to yield identical core proteins with a serine as the NH2-terminal residue. These results indicate that ATPase subunit 6 is synthesized normally in Ogura radish, and that it is unlikely that the atp6 locus is associated with Ogura cytoplasmic male sterility.

Characterization of the radish mitochondrial orfB locus: possible relationship with male sterility in Ogura radish

The orfB locus of the normal (fertile) and Ogura (male-sterile) radish mitochondrial genomes has been characterized in order to determine if this region, which has previously been correlated with cytoplasmic male sterility (CMS) in Brassica napus cybrids (Bonhomme et al. 1991; Temple et al. 1992), could also be involved in radish CMS. In normal radish, orfB is expressed as a 600-nucleotide (nt) transcript. In Ogura radish, orfB is present as the second gene of a 1200-nt transcript that also contains a 138-codon open reading frame (orf138). Sequences showing similarity to orf138 are present in normal radish, but are not expressed.

Editing of rps3/rpl16 transcripts creates a premature truncation of the rpl16 open reading frame

Overlapping open reading frames corresponding to maize mitochondrial genes rps3 and rpl16 have been found in Petunia mitochondrial DNA. The DNA region associated with these two genes is part of the Petunia mitochondrial recombination repeat and is iterated three times. Analysis of transcripts from these genes shows that there is RNA editing of the coding regions and that one of the editing sites detected in the open reading frame overlap creates a premature stop codon in the rpl16 sequence. No transcripts were detected that were unedited at this site. Thus, in Petunia editing of rpl16 appears to render this gene nonfunctional.

RNA editing gives a new meaning to the genetic information in mitochondria and chloroplasts

RNA editing in plant mitochondria and chloroplasts alters mRNA sequences to code for different proteins than the DNA. Most of these C-to-U transitions occur in open reading frames, but a few are observed in intron sequences. Influences of the nuclear genome on editing patterns suggest that cytoplasmic factors participate in this process.

Editing of transfer RNAs in Acanthamoeba castellanii mitochondria

With the discovery of RNA editing, a process whereby the primary sequence of RNA is altered after transcription, traditional concepts of genetic information transfer had to be revised. The known RNA editing systems act mainly on messenger RNAs, introducing sequence changes that alter their coding properties. An editing system that acts on transfer RNAs is described here. In the mitochondria of Acanthamoeba castellanii, an amoeboid protozoan, certain transfer RNAs differ in sequence from the genes that encode them. The changes consist of single-nucleotide conversions (U to A, U to G, and A to G) that appear to arise posttranscriptionally, are localized in the acceptor stem, and have the effect of correcting mismatched base pairs. Editing thus restores the base pairing expected of a normal transfer RNA in this region.

RNA editing of a chimeric maize mitochondrial gene transcript is sequence specific

RNA editing was analysed in the mitochondrial ATPase complex subunit 6 gene (atp6) transcripts of the C male-sterile cytoplasm (cms-C) of maize. The only copy of atp6 in cms-C, designated C-atp6, is a triple gene fusion product comprised of DNA sequences derived from atp9, atp6, and an unknown origin. Sequences of cDNAs revealed 19 C to U alterations resulting in 16 amino acid residue changes compared to the genomic sequence. The only C to U edit in the 39-nucleotide sequence similar to atp9 was comparable to a change in the complete atp9 mRNAs of Petunia, Oenothera, wheat, and sorghum. The 442 nucleotides of unknown origin were not edited. The 18 editing events within the atp6 homologous region were similar to those in the atp6 transcripts of sorghum. RNA editing in maize C-atp6 transcripts introduces a translational stop codon at the same position where it is created by editing in sorghum and Oenothera atp6 mRNAs and is already present in atp6 open reading frames of most other plant and non-plant organisms. Our results, along with other reports on editing in chimeric transcripts, indicate that RNA editing is not influenced by rearrangements but instead is sequence specific.

RNA editing of rapeseed mitochondrial atp9 transcripts: RNA editing changes four amino acids, but termination codon is already encoded by genomic sequence

The gene encoding subunit 9 of Fo-ATPase of rapeseed mitochondria has been isolated. The complete genomic DNA sequence and cDNA sequence corresponding to the atp9 gene transcript have 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 comparison of cDNA sequences to genomic one, four modifications, C-to-U conversions, have been found. When compared with RNA editing patterns of atp9 transcripts among plant mitochondria, that of rapeseed atp9 transcript is more simple; there are only four editing sites on the coding region, and its termination codon is already encoded by genomic sequence.

A single nuclear gene specifies the abundance and extent of RNA editing of a plant mitochondrial transcript

A number of cytosines are altered to be recognized as uridines in transcripts of the NADH-dehydrogenase subunit 3 (nad3) gene in the mitochondria of the higher plant Petunia hybrida. Here we show that the extent of editing for three of the edit sites, all of which change the encoded amino acid, varies between different Petunia lines. Genetic analysis indicates that a single nuclear gene is responsible for this variation. Interestingly, according to RNA blot hybridization analysis, RNA editing extent and transcript abundance are correlated. This observation is consistent with the hypothesis that RNA editing is a post-transcriptional event.

RNA editing of atp6 transcripts from male-sterile and normal cytoplasms of rapeseed (Brassica napus L.)

The complete cDNA sequence corresponding to the rapeseed atp6 gene transcript (coding for subunit 6 of F0-ATPase) 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. Only one modification, a C-to-U conversion, has been found when compared to the genomic mitochondrial DNA sequence. Comparison of the extent and frequency of RNA editing of the pol cytoplasmic male sterile (cms) atp6 transcript with those of normal atp6 transcript indicates that there is no variation between the editing status of the atp6 transcripts from pol cms and normal cytoplasms.

Conserved sequence blocks 5' to start codons of plant mitochondrial genes

Three sequence blocks of 10-12 bp are conserved in sequence and order 5' to putative start codons of several higher-plant mitochondrial genes. At least 25 examples were found, primarily associated with coxII, atp6, and orf25, in monocotyledons and dicotyledons. The proximal block can be 9 bp from start codons, and the three blocks generally occur within 100 bp 5' of start codons. In three examples 5' termini of the blocks represent recombination breakpoints, resulting in conservation of the blocks in resultant configurations. The two proximal blocks can form a secondary structure motif. The occurrence of the blocks near start codons, and conserved sequence and order, is consistent with a possible role in translation initiation or regulation.

Editing of mitochondrial atp9 transcripts from two sorghum lines

Genomic and cDNA sequences of the ATP synthase complex subunit 9 (atp9) genes from two sorghum lines were determined. Sequences of cDNAs revealed eight C to U transcript editing events resulting in six amino acid changes and a new stop codon which eliminated 12 carboxy-terminal residues, compared to the genomic sequence. Sorghum atp9 has a unique five-residue amino-extension relative to other higher plants. The resulting predicted 79-residue gene product has a molecular weight of 8.179 kDa. The predicted phe-val-phe carboxy-terminus is identical to that from cDNA sequences of wheat, Oenothera, and petunia. Partial editing of transcripts was detected in each sorghum line.