A termination codon is created by RNA editing in the petunia atp9 transcript

Genomic insights into the clonal reproductive Opuntia cochenillifera: mitochondrial and chloroplast genomes of the cochineal cactus for enhanced understanding of structural dynamics and evolutionary implications

Background

The cochineal cactus (Opuntia cochenillifera), notable for its substantial agricultural and industrial applications, predominantly undergoes clonal reproduction, which presents significant challenges in breeding and germplasm innovation. Recent developments in mitochondrial genome engineering offer promising avenues for introducing heritable mutations, potentially facilitating selective sexual reproduction through the creation of cytoplasmic male sterile genotypes. However, the lack of comprehensive mitochondrial genome information for Opuntia species hinders these efforts. Here, we intended to sequence and characterize its mitochondrial genome to maximize the potential of its genomes for evolutionary studies, molecular breeding, and molecular marker developments.

Results

We sequenced the total DNA of the O. cochenillifera using DNBSEQ and Nanopore platforms. The mitochondrial genome was then assembled using a hybrid assembly strategy using Unicycler software. We found that the mitochondrial genome of O. cochenillifera has a length of 1,156,235 bp, a GC content of 43.06%, and contains 54 unique protein-coding genes and 346 simple repeats. Comparative genomic analysis revealed 48 homologous fragments shared between mitochondrial and chloroplast genomes, with a total length of 47,935 bp. Additionally, the comparison of mitochondrial genomes from four Cactaceae species highlighted their dynamic nature and frequent mitogenomic reorganizations.

Conclusion

Our study provides a new perspective on the evolution of the organelle genome and its potential application in genetic breeding. These findings offer valuable insights into the mitochondrial genetics of Cactaceae, potentially facilitating future research and breeding programs aimed at enhancing the genetic diversity and adaptability of O. cochenillifera by leveraging its unique mitochondrial genome characteristics.

Effect of salinity on ccmfn gene RNA editing of mitochondria in wild barley and uncommon types of RNA editing

The primary function of mitochondria is cellular respiration and energy production. Cytochrome C complex is an essential complex that transports electrons in the respiratory chain between complex III and complex IV. One of this complex's main subunits is CcmFN, which is believed to be crucial for holocytochrome assembly. In wild-type plant Hordeum vulgare subsp. spontaneum, four ccmfn cDNAs are subjected to high salt stress (500 mM salinity), 0 h (or control) (GenBank accession no. ON764850), after 2 h (GenBank accession no. ON7648515), after 12 h (GenBank accession no. ON764852), and after 24 h (GenBank accession no. ON764853) and mtDNA of ccmfn gene (GenBank accession no. ON764854). Using raw data from RNA-seq, 47 sites with nucleotide and amino acid modifications were detected. There were ten different RNA editing types, with most of them are C to U. Unusual editing types in plants have also been found, such as A to C, C to A, A to G, A to U, T to A, T to C, C to G, G to C, and T to G. High levels of editing were observed in control as well as treatments of salinity stress. Amino acid changes were found in 43 sites; nearly all showed hydrophilic to hydrophilic alterations. Only C749 showed regulation under salinity stress.

C-to-U RNA Editing: A Site Directed RNA Editing Tool for Restoration of Genetic Code

The restoration of genetic code by editing mutated genes is a potential method for the treatment of genetic diseases/disorders. Genetic disorders are caused by the point mutations of thymine (T) to cytidine (C) or guanosine (G) to adenine (A), for which gene editing (editing of mutated genes) is a promising therapeutic technique. In C-to-Uridine (U) RNA editing, it converts the base C-to-U in RNA molecules and leads to nonsynonymous changes when occurring in coding regions; however, for G-to-A mutations, A-to-I editing occurs. Editing of C-to-U is not as physiologically common as that of A-to-I editing. Although hundreds to thousands of coding sites have been found to be C-to-U edited or editable in humans, the biological significance of this phenomenon remains elusive. In this review, we have tried to provide detailed information on physiological and artificial approaches for C-to-U RNA editing.

FEDRO: a software tool for the automatic discovery of candidate ORFs in plants with c →u RNA editing

BACKGROUND

RNA editing is an important mechanism for gene expression in plants organelles. It alters the direct transfer of genetic information from DNA to proteins, due to the introduction of differences between RNAs and the corresponding coding DNA sequences. Software tools successful for the search of genes in other organisms not always are able to correctly perform this task in plants organellar genomes. Moreover, the available software tools predicting RNA editing events utilise algorithms that do not account for events which may generate a novel start codon.

RESULTS

We present FEDRO, a Java software tool implementing a novel strategy to generate candidate Open Reading Frames (ORFs) resulting from Cytidine to Uridine (c→u) editing substitutions which occur in the mitochondrial genome (mtDNA) of a given input plant. The goal is to predict putative proteins of plants mitochondria that have not been yet annotated. In order to validate the generated ORFs, a screening is performed by checking for sequence similarity or presence in active transcripts of the same or similar organisms. We illustrate the functionalities of our framework on a model organism.

CONCLUSIONS

The proposed tool may be used also on other organisms and genomes. FEDRO is publicly available at http://math.unipa.it/rombo/FEDRO .

RNA editing of cytochrome c maturation transcripts is responsive to the energy status of leaf cells in Arabidopsis thaliana

Overexpression of AtPAP2, a phosphatase located on the outer membranes of chloroplasts and mitochondria, leads to higher energy outputs from these organelles. AtPAP2 interacts with seven MORF proteins of the editosome complex. RNA-sequencing analysis showed that the editing degrees of most sites did not differ significantly between OE and WT, except some sites on the transcripts of several cytochrome c maturation (Ccm) genes. Western blotting of 2D BN-PAGE showed that the patterns of CcmF_N1 polypeptides were different between the lines. We proposed that AtPAP2 may influence cytochrome c biogenesis by modulating RNA editing through its interaction with MORF proteins.

Characterization of the complete mitochondrial genome of the Grey-backed Shrike, Lanius tephronotus (Aves: Passeriformes): the first representative of the family Laniidae with a novel CAA stop codon at the end of cox2 gene

The complete Grey-backed Shrike mitochondrial genome has been sequenced to be 16,820 bp in length, consisting of 37 encode genes: 13 protein-coding genes, 2 ribosomal RNA genes, and 22 transfer RNA genes. In addition, a single control region was also observed. Compared with other reported Passeriformes mtgenome sequences, three bases CAA were detected at the end of Lanius tephronotus cox2 gene with the downstream adjacent base T. The first base of CAA probably occurred C to U transcript editing event resulting in a normal stop codon UAA.

A complete sequence and transcriptomic analyses of date palm (Phoenix dactylifera L.) mitochondrial genome

Based on next-generation sequencing data, we assembled the mitochondrial (mt) genome of date palm (Phoenix dactylifera L.) into a circular molecule of 715,001 bp in length. The mt genome of P. dactylifera encodes 38 proteins, 30 tRNAs, and 3 ribosomal RNAs, which constitute a gene content of 6.5% (46,770 bp) over the full length. The rest, 93.5% of the genome sequence, is comprised of cp (chloroplast)-derived (10.3% with respect to the whole genome length) and non-coding sequences. In the non-coding regions, there are 0.33% tandem and 2.3% long repeats. Our transcriptomic data from eight tissues (root, seed, bud, fruit, green leaf, yellow leaf, female flower, and male flower) showed higher gene expression levels in male flower, root, bud, and female flower, as compared to four other tissues. We identified 120 potential SNPs among three date palm cultivars (Khalas, Fahal, and Sukry), and successfully found seven SNPs in the coding sequences. A phylogenetic analysis, based on 22 conserved genes of 15 representative plant mitochondria, showed that P. dactylifera positions at the root of all sequenced monocot mt genomes. In addition, consistent with previous discoveries, there are three co-transcribed gene clusters–18S-5S rRNA, rps3-rpl16 and nad3-rps12–in P. dactylifera, which are highly conserved among all known mitochondrial genomes of angiosperms.

AtECB2, a pentatricopeptide repeat protein, is required for chloroplast transcript accD RNA editing and early chloroplast biogenesis in Arabidopsis thaliana

Chloroplast biogenesis is a complex process in higher plants. Screening chloroplast biogenesis mutants, and elucidating their molecular mechanisms, will provide insight into the process of chloroplast biogenesis. In this paper, we obtained an early chloroplast biogenesis mutant atecb2 that displayed albino cotyledons and was seedling lethal. Microscopy observations revealed that the chloroplast of atecb2 mutants lacked an organized thylakoid membrane. The AtECB2 gene, which is highly expressed in cotyledons and seedlings, encodes a pentatricopeptide repeat protein (PPR) with a C-terminal DYW domain. The AtECB2 protein is localized in the chloroplast, and contains a conserved HxEx(n)CxxC motif that is similar to the activated site of cytidine deaminase. The AtECB2 mutation affects the expression pattern of plastid-encoded genes. Immunoblot analyses showed that the levels of photosynthetic proteins decreased substantially in atecb2 mutants. Inspection of all reported plastid RNA editing sites revealed that one editing site, accD, is not edited in atecb2 mutants. Therefore, the AtECB2 protein must regulate the RNA editing of this site, and the dysfunctional AccD protein from the unedited RNA molecules could lead to the mutated phenotype. All of these results indicate that AtECB2 is required for chloroplast transcript accD RNA editing and early chloroplast biogenesis in Arabidopsis thaliana.

LPA66 is required for editing psbF chloroplast transcripts in Arabidopsis

To gain insight into the molecular mechanism of RNA editing, we have characterized the low psii accumulation66 (lpa66) Arabidopsis (Arabidopsis thaliana) mutant, which displays a high chlorophyll fluorescence phenotype. Its perturbed chlorophyll fluorescence is reflected in reduced levels of photosystem II (PSII) proteins. In vivo protein labeling showed that synthesis rates of the PSII reaction center protein D1/D2 were lower, and turnover rates of PSII core proteins higher, than in wild-type counterparts. The assembly of newly synthesized proteins into PSII occurs in the lpa66 mutant but with reduced efficiency compared with the wild type. LPA66 encodes a chloroplast protein of the pentatricopeptide repeat family. In lpa66 mutants, editing of psbF that converts serine to phenylalanine is specifically impaired. Thus, LPA66 is specifically required for editing the psbF transcripts in Arabidopsis, and the amino acid alternation due to lack of editing strongly affects the efficiency of the assembly of PSII complexes.

A comparative genomics approach identifies a PPR-DYW protein that is essential for C-to-U editing of the Arabidopsis chloroplast accD transcript

Several nuclear-encoded proteins containing pentatricopeptide repeat (PPR) motifs have previously been identified to be trans-factors essential for particular chloroplast RNA editing events through analysis of mutants affected in chloroplast biogenesis or function. Other PPR genes are known to encode proteins involved in other aspects of organelle RNA metabolism. A function has not been assigned to most members of the large plant PPR gene family. Arabidopsis and rice each contain over 400 PPR genes, of which about a fifth exhibit a C-terminal DYW domain. We describe here a comparative genomics approach that will facilitate identification of the role of RNA-binding proteins in organelle RNA metabolism. We have implemented this strategy to identify an Arabidopsis nuclear-encoded gene RARE1 that is required for editing of the chloroplast accD transcript. RARE1 carries 15 PPR motifs, an E/E+ and a DYW domain, whereas previously reported editing factors CRR4, CRR21, and CLB19 lack a DYW domain. The accD gene encodes the beta carboxyltransferase subunit of acetyl coA carboxylase, which catalyzes the first step in fatty acid biosynthesis in chloroplasts. Despite a lack of accD C794 editing and lack of restoration of an evolutionarily conserved leucine residue in the beta carboxyltransferase protein, rare1 mutants are unexpectedly robust and reproduce under growth room conditions. Previously the serine-to-leucine alteration caused by editing was deemed essential in the light of the finding that a recombinantly expressed "unedited" form of the pea acetyl coA carboxylase was catalytically inactive.

Organellar RNA editing and plant-specific extensions of pentatricopeptide repeat proteins in jungermanniid but not in marchantiid liverworts

The pyrimidine exchange type of RNA editing in land plant (embryophyte) organelles has largely remained an enigma with respect to its biochemical mechanisms, the underlying specificities, and its raison d'être. Apparently arising with the earliest embryophytes, RNA editing is conspicuously absent in one clade of liverworts, the complex thalloid Marchantiidae. Several lines of evidence suggest that the large gene family of organelle-targeted RNA-binding pentatricopeptide repeat (PPR) proteins plays a fundamental role in the sequence-specific editing of organelle transcripts. We here describe the identification of PPR protein genes with plant-specific carboxyterminal (C-terminal) sequence signatures (E, E+, and DYW domains) in ferns, lycopodiophytes, mosses, hornworts, and jungermanniid liverworts, one subclass of the basal most clade of embryophytes, on DNA and cDNA level. In contrast, we were unable to identify these genes in a wide sampling of marchantiid liverworts (including the phylogenetic basal genus Blasia)--taxa for which no RNA editing is observed in the organelle transcripts. On the other hand, we found significant diversity of this type of PPR proteins also in Haplomitrium, a genus with an extremely high rate of RNA editing and a phylogenetic placement basal to all other liverworts. Although the presence of modularly extended PPR proteins correlates well with organelle RNA editing, the now apparent complete loss of an entire gene family from one clade of embryophytes, the marchantiid liverworts, remains puzzling.

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.

Fully edited and partially edited nad9 transcripts differ in size and both are associated with polysomes in potato mitochondria

Two classes of nad9 transcripts are present at different abundances in the steady-state RNA pool of potato mitochondria. The 5'- and 3' termini of the transcripts were determined by primer extension and S1 nuclease protection analyses respectively. Using two primer pairs that will either specifically amplify the larger transcript or amplify both the larger and the smaller transcripts in RT-PCR analyses it was found that the larger nad9 transcripts are partially edited, while the smaller transcripts are fully edited. Both the larger and the smaller transcripts were found to be associated with mitochondrial polysomes. The polysome association was found to be sensitive to EDTA and puromycin treatment. Therefore, both fully and partially edited nad9 transcripts appear to be engaged in translation.

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.

Pervasive migration of organellar DNA to the nucleus in plants

A surprisingly large number of plant nuclear DNA sequences inferred to be remnants of chloroplast and mitochondrial DNA migration events were detected through computer-assisted database searches. Nineteen independent organellar DNA insertions, with a median size of 117 bp (range of 38 to > 785 bp), occur in the proximity of 15 nuclear genes. One fragment appears to have been passed through a RNA intermediate, based on the presence of an edited version of the mitochondrial gene in the nucleus. Tandemly arranged fragments from disparate regions of organellar genomes and from different organellar genomes indicate that the fragments joined together from an intracellular pool of RNA and/or DNA before they integrated into the nuclear genome. Comparisons of integrated sequences to genes lacking the insertions, as well as the occurrence of coligated fragments, support a model of random integration by end joining. All transferred sequences were found in noncoding regions, but the positioning of organellar-derived DNA in introns, as well as regions 5' and 3' to nuclear genes, suggests that the random integration of organellar DNA has the potential to influence gene expression patterns. A semiquantitative estimate was performed on the amount of organellar DNA being transferred and assimilated into the nucleus. Based on this database survey, we estimate that 3-7% of the plant nuclear genomic sequence files contain organellar-derived DNA. The timing and the magnitude of genetic flux to the nuclear genome suggest that random integration is a substantial and ongoing process for creating sequence variation.

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.

A plant mitochondrial sequence transcribed in transgenic tobacco chloroplasts is not edited

RNA editing occurs in two higher-plant organelles, chloroplasts and mitochondria. Because chloroplasts and mitochondria exhibit some similarity in editing site selection, we investigated whether mitochondrial RNA sequences could be edited in chloroplasts. We produced transgenic tobacco plants that contained chimeric genes in which the second exon of a Petunia hybrida mitochondrial coxII gene was under the control of chloroplast gene regulatory sequences. coxII transcripts accumulated to low or high levels in transgenic chloroplasts containing chimeric genes with the plastid ribosomal protein gene rps16 or the rRNA operon promoter, respectively. Exon 2 of coxII was chosen because it carries seven editing sites and is edited in petunia mitochondria even when located in an abnormal context in an aberrant recombined gene. When editing of the coxII transcripts in transgenic chloroplasts was examined, no RNA editing at any of the usual sites was detected, nor was there any novel editing at any other sites. These results indicate that the RNA editing mechanisms of chloroplasts and mitochondria are not identical but must have at least some organelle-specific components.

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.

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.

Transcription of the gene coding for subunit 9 of ATP synthase in rice mitochondria

Transcription of the single-copy rice mitochondrial atp9 gene has been analyzed. We propose that there is a 0.65 kb primary transcript that is processed to an abundant 0.45 kb mRNA; a sequence motif at the 5' terminus of the 0.65 kb transcript shares 9 out of 11 nucleotides homology to the consensus promoter proposed for maize. There are several 3' termini based on RNase protection, and these termini map within or just distal to inverted repeats that could fold into a double stem-loop structure.

RNA editing of the barley (Hordeum vulgare) mitochondrial ATP synthase subunit 9

The barley (Hordeum vulgare) FO-ATP synthase subunit 9 (atp9) was isolated from the mitochondrial DNA. Two copies of atp9 are present in barley mitochondria and 2 major transcripts of 2.7 kb and 1.2 kb were detected on RNA blots. RNA editing as C-to-U conversion occurs in barley atp9 in seven positions. Five of these seven positions lead to an amino acid change whereas two conversions are silent. The editing positions of barley were found to be identical to those of wheat. Whereas in wheat, Oenothera and Petunia all the atp9 transcripts were fully edited, 24% of the barley cDNA clones were partially edited as compared to 10% partially edited clones in wheat.

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.

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.

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

Sequencing of sorghum mitochondrial atp6 cDNA clones revealed 19 C-to-U transcript editing events within a 756 bp-conserved core gene; three were silent and 16 resulted in 15 amino acid changes. Only one edit, which was silent, was found in the 381 bp amino-extension to the core gene. Eleven of the 15 changed amino acids were identical with or else represented conservative changes compared to yeast atp6. Editing of a CAA codon to TAA truncates the carboxy-terminus to a position identical to that of yeast. The frequency of editing at sites which change amino acids was very high in contrast to partial editing at silent, third base, sites.

Editing of pre-mRNAs can occur before cis- and trans-splicing in Petunia mitochondria

Plant mitochondrial mRNAs have recently been shown to undergo editing, involving cytidine-to-uridine changes relative to the DNA sequence. We have examined the temporal relationship of editing and intron removal in coxII mRNAs in Petunia mitochondria. By using differential hybridization to probes specific for edited and unedited RNA and by sequencing of individual unspliced coxII pre-mRNA cDNAs, we found that RNA editing at any editing site can precede the splicing event. Similar results were obtained from examinations of pre-mRNA cDNAs of nad1, a gene composed of multiple exons that are both cis and trans spliced. Thus, intron removal is not required before editing can occur. The existence of editing intermediates indicates that the editing process is not strictly coincident with transcription.

Multiple trans-splicing events are required to produce a mature nad1 transcript in a plant mitochondrion

The mitochondrial gene encoding NADH dehydrogenase subunit 1 (nad1) in Petunia hybrida is split into five exons, a, b, c, d, and e. With the use of a complete restriction map of the 443-kb Petunia mitochondrial genome, we have cloned these exons and mapped their location. Exon a is located 130 kb away from and in the opposite orientation from exons b and c. Exon d maps 95 kb away and in the opposite orientation from exons b and c. Exons d and e are separated by 190 kb. By performing the polymerase chain reaction on Petunia cDNAs, we have shown that transcripts from these five exons are joined via a series of cis- and trans-splicing events to create a mature nad1 transcript. In addition, we have found 23 C----U RNA edit sites in Petunia nad1. RNA editing changes 19 of the amino acids predicted by the genomic sequence.

Editing of pre-mRNAs can occur before cis- and trans-splicing in Petunia mitochondria

Plant mitochondrial mRNAs have recently been shown to undergo editing, involving cytidine-to-uridine changes relative to the DNA sequence. We have examined the temporal relationship of editing and intron removal in coxII mRNAs in Petunia mitochondria. By using differential hybridization to probes specific for edited and unedited RNA and by sequencing of individual unspliced coxII pre-mRNA cDNAs, we found that RNA editing at any editing site can precede the splicing event. Similar results were obtained from examinations of pre-mRNA cDNAs of nad1, a gene composed of multiple exons that are both cis and trans spliced. Thus, intron removal is not required before editing can occur. The existence of editing intermediates indicates that the editing process is not strictly coincident with transcription.