Control of gene expression by base deamination: the case of RNA editing in wheat mitochondria

The complete chloroplast genome sequence of the medicinal plant Abrus pulchellus subsp. cantoniensis: genome structure, comparative and phylogenetic relationship analysis

Abrus pulchellus subsp. cantoniensis, an endemic medicinal plant in southern China, is clinically used to treat jaundice hepatitis, cholecystitis, stomachache and breast carbuncle. Here, we assembled and analyzed the first complete chloroplast (cp) genome of A. pulchellus subsp. cantoniensis. The A. pulchellus subsp. cantoniensis cp genome size is 156,497 bp with 36.5% GC content. The cp genome encodes 130 genes, including 77 protein-coding genes, 30 tRNA genes and four rRNA genes, of which 19 genes are duplicated in the inverted repeats (IR) regions. A total of 30 codons exhibited codon usage bias with A/U-ending. Moreover, 53 putative RNA editing sites were predicted in 20 genes, all of which were cytidine to thymine transitions. Repeat sequence analysis identified 45 repeat structures and 125 simple-sequence repeats (SSRs) in A. pulchellus subsp. cantoniensis cp genome. In addition, 19 mononucleotides (located in atpB, trnV-UAC, ycf3, atpF, rps16, rps18, clpP, rpl16, trnG-UCC and ndhA) and three compound SSRs (located in ndhA, atpB and rpl16) showed species specificity between A. pulchellus subsp. cantoniensis and Abrus precatorius, which might be informative sources for developing molecular markers for species identification. Furthermore, phylogenetic analysis inferred that A. pulchellus subsp. cantoniensis was closely related to A. precatorius, and the genus Abrus formed a subclade with Canavalia in the Millettioid/Phaseoloid clade. These data provide a valuable resource to facilitate the evolutionary relationship and species identification of this species.

Molecular and Functional Diversity of RNA Editing in Plant Mitochondria

RNA editing is a fundamental biochemical process relating to the modification of nucleotides in messenger RNAs of functional genes in cells. RNA editing leads to re-establishment of conserved amino acid residues for functional proteins in nuclei, chloroplasts, and mitochondria. Identification of RNA editing factors that contributes to target site recognition increases our understanding of RNA editing mechanisms. Significant progress has been made in recent years in RNA editing studies for both animal and plant cells. RNA editing in nuclei and mitochondria of animal cells and in chloroplast of plant cells has been extensively documented and reviewed. RNA editing has been also extensively documented on plant mitochondria. However, functional diversity of RNA editing factors in plant mitochondria is not overviewed. Here, we review the biological significance of RNA editing, recent progress on the molecular mechanisms of RNA editing process, and function diversity of editing factors in plant mitochondrial research. We will focus on: (1) pentatricopeptide repeat proteins in Arabidopsis and in crop plants; (2) the progress of RNA editing process in plant mitochondria; (3) RNA editing-related RNA splicing; (4) RNA editing associated flower development; (5) RNA editing modulated male sterile; (6) RNA editing-regulated cell signaling; and (7) RNA editing involving abiotic stress. Advances described in this review will be valuable in expanding our understanding in RNA editing. The diverse functions of RNA editing in plant mitochondria will shed light on the investigation of molecular mechanisms that underlies plant development and abiotic stress tolerance.

In organello gene expression and RNA editing studies by electroporation-mediated transformation of isolated plant mitochondria

Plant mitochondrial gene expression is a complex process involving multiple steps such as transcription, cis- and trans-splicing, RNA trimming, RNA editing, and translation. One of the main hurdles in understanding more about these processes has been the inability to incorporate engineered genes into mitochondria. We recently reported an in organello approach on the basis of the introduction of foreign DNA into isolated plant mitochondria by electroporation. This procedure allows the investigation of transcriptional and posttranscriptional processes, such as splicing and RNA editing, by use of site-directed mutagenesis. Foreign gene expression in organello is strongly dependent on the functional status of mitochondria, thus providing relevant information in conditions closer to the situation found in vivo. The study of mutants that affect RNA splicing and editing provides a novel and powerful method to explain the role of specific sequences involved in these processes. Here we describe a protocol to "transform" isolated plant mitochondria that has allowed us to investigate successfully some aspects of RNA editing.

Gene expression studies in isolated mitochondria: Solanum tuberosum rps10 is recognized by cognate potato but not by the transcription, splicing and editing machinery of wheat mitochondria

The complex gene expression mechanisms that occur in plant mitochondria, such as RNA editing and splicing, are not yet well understood. RNA editing in higher plant mitochondria is a highly specific process which modifies mRNA sequences by C-to-U conversions. It has been suggested that in some cases this process is required for splicing. Here, we use an experimental model based on the introduction of DNA into isolated mitochondria by electroporation to study organellar gene expression events. Our aim was to compare processing and editing of potato small ribosomal protein 10 gene (rps10) transcripts in heterologous (wheat mitochondria) and homologous (potato mitochondria) contexts. rps10 is a suitable model because it contains a group II intron, is absent in wheat mitochondria but is actively expressed in potato mitochondria, where transcripts are spliced and undergo five C-to-U editing events. For this purpose, conditions for electroporating isolated potato mitochondria were established. rps10 was placed under the control of either potato or wheat cox2 promoters. We found that rps10 was only transcribed under the control of a cognate promoter. In wheat mitochondria, rps10 transcripts were neither spliced nor edited while they are correctly processed in potato mitochondria. Interestingly, a wheat editing site grafted into rps10 was not recognized by wheat mitochondria but was correctly edited in potato mitochondria. Taken together, these results suggest that editing might occur only when the transcripts are engaged in processing and that they would not be available to editing factors outside of a putative RNA maturation machinery complex.

Editing of the grapevine mitochondrial cytochrome b mRNA and molecular modeling of the protein

Cytochrome b (COB), the central catalytic subunit of ubiquinol cytochrome c reductase, is a component of the transmembrane electron transfer chain that generates proton motive force. Some plant COB mRNAs are processed by RNA editing, which changes the gene coding sequence. This report presents the sequences of the grapevine (Vitis vinifera L.) mitochondrial gene for apocytochrome b (cob), the edited mRNA and the deduced protein. Grapevine COB is 393 amino acids long and is 98% identical to homologs in rapeseed, Arabidopsis thaliana and Oenothera sp. Twenty-one C-U editing sites were identified in the grapevine cob mRNA, resulting in 20 amino acid changes. These changes increase the overall hydrophobicity of the protein and result in a more conserved protein. Molecular modeling of grapevine COB shows that residues changed by RNA editing fit the secondary structure characteristic of an integral membrane protein. This is the first complete mitochondrial gene reported for grapevine. Novel RNA editing sites were identified in grapevine cob, which have not been previously reported for other plants.

From gene to protein in higher plant mitochondria

Higher plant mitochondria contain a genetic system with a genome, transcription and translation processes, which have to be logistically integrated with the two other genomes in the nucleus and the plastid. In plant mitochondria, after transcripts have been synthesised, at least in some cases by a phage-type RNA polymerase, they have to go through a complex processing apparatus, which depends on protein factors imported from the cytosol. Processing involves cis- and trans-splicing, internal RNA editing and maturation at the transcript termini, these steps often occurring in parallel. Transcript life is terminated by RNA degradation mechanisms, one of which involves polyadenylation. RNA metabolism seems to be a key element of the regulation of gene expression in higher plant mitochondria.