High conservation of a 5' element required for RNA editing of a C target in chloroplast psbE transcripts

Divergence of RNA editing among Arabidopsis species

RNA editing altered the RNA sequence by replacing the C nucleotide to U in the organellar genomes of plants. RNA editing status sometimes differed among distant species. The pattern of conservation and variation of RNA editing status made it possible to evaluate evolutionary mechanisms impacting functional aspects of RNA editing. In this study, divergence of RNA editing in the chloroplast genome among Arabidopsis species was analyzed to determine 9 losses and 1 gain in RNA editing. All changes in A. thaliana lineage resulted from changes to the chloroplast genome sequence, whereas changes in the A. lyrata / halleri lineage were possibly due to exclusive changes in the nuclear editing factors. One loss of RNA editing in A. lyrata was caused by a deficiency in the PPR gene OTP80. The changes in RNA editing occurred approximately every two million years and were not observed at functionally important sites. These results highlight the conserved nature of RNA editing status suggesting the importance of RNA editing during evolution.

Pentatricopeptide repeat proteins in plants

Pentatricopeptide repeat (PPR) proteins constitute one of the largest protein families in land plants, with more than 400 members in most species. Over the past decade, much has been learned about the molecular functions of these proteins, where they act in the cell, and what physiological roles they play during plant growth and development. A typical PPR protein is targeted to mitochondria or chloroplasts, binds one or several organellar transcripts, and influences their expression by altering RNA sequence, turnover, processing, or translation. Their combined action has profound effects on organelle biogenesis and function and, consequently, on photosynthesis, respiration, plant development, and environmental responses. Recent breakthroughs in understanding how PPR proteins recognize RNA sequences through modular base-specific contacts will help match proteins to potential binding sites and provide a pathway toward designing synthetic RNA-binding proteins aimed at desired targets.

The chloroplast genome of Pellia endiviifolia: gene content, RNA-editing pattern, and the origin of chloroplast editing

RNA editing is a post-transcriptional process that can act upon transcripts from mitochondrial, nuclear, and chloroplast genomes. In chloroplasts, single-nucleotide conversions in mRNAs via RNA editing occur at different frequencies across the plant kingdom. These range from several hundred edited sites in some mosses and ferns to lower frequencies in seed plants and the complete lack of RNA editing in the liverwort Marchantia polymorpha. Here, we report the sequence and edited sites of the chloroplast genome from the liverwort Pellia endiviifolia. The type and frequency of chloroplast RNA editing display a pattern highly similar to that in seed plants. Analyses of the C to U conversions and the genomic context in which the editing sites are embedded provide evidence in favor of the hypothesis that chloroplast RNA editing evolved to compensate mutations in the first land plants.

Molecular evolution of pentatricopeptide repeat genes reveals truncation in species lacking an editing target and structural domains under distinct selective pressures

BACKGROUND

Pentatricopeptide repeat (PPR) proteins are required for numerous RNA processing events in plant organelles including C-to-U editing, splicing, stabilization, and cleavage. Fifteen PPR proteins are known to be required for RNA editing at 21 sites in Arabidopsis chloroplasts, and belong to the PLS class of PPR proteins. In this study, we investigate the co-evolution of four PPR genes (CRR4, CRR21, CLB19, and OTP82) and their six editing targets in Brassicaceae species. PPR genes are composed of approximately 10 to 20 tandem repeats and each repeat has two α-helical regions, helix A and helix B, that are separated by short coil regions. Each repeat and structural feature was examined to determine the selective pressures on these regions.

RESULTS

All of the PPR genes examined are under strong negative selection. Multiple independent losses of editing site targets are observed for both CRR21 and OTP82. In several species lacking the known editing target for CRR21, PPR genes are truncated near the 17th PPR repeat. The coding sequences of the truncated CRR21 genes are maintained under strong negative selection; however, the 3' UTR sequences beyond the truncation site have substantially diverged. Phylogenetic analyses of four PPR genes show that sequences corresponding to helix A are high compared to helix B sequences. Differential evolutionary selection of helix A versus helix B is observed in both plant and mammalian PPR genes.

CONCLUSION

PPR genes and their cognate editing sites are mutually constrained in evolution. Editing sites are frequently lost by replacement of an edited C with a genomic T. After the loss of an editing site, the PPR genes are observed with three outcomes: first, few changes are detected in some cases; second, the PPR gene is present as a pseudogene; and third, the PPR gene is present but truncated in the C-terminal region. The retention of truncated forms of CRR21 that are maintained under strong negative selection even in the absence of an editing site target suggests that unrecognized function(s) might exist for this PPR protein. PPR gene sequences that encode helix A are under strong selection, and could be involved in RNA substrate recognition.

Pentatricopeptide repeat proteins constrain genome evolution in chloroplasts

Higher plants encode hundreds of pentatricopeptide repeat proteins (PPRs) that are involved in several types of RNA processing reactions. Most PPR genes are predicted to be targeted to chloroplasts or mitochondria, and many are known to affect organellar gene expression. In some cases, RNA binding has been directly demonstrated, and the sequences of the cis-elements are known. In this work, we demonstrate that RNA cis-elements recognized by PPRs are constrained in chloroplast genome evolution. Cis-elements for two PPR genes and several RNA editing sites were analyzed for sequence changes by pairwise nucleotide substitution frequency, pairwise indel frequency, and maximum likelihood (ML) phylogenetic distances. All three of these analyses demonstrated that sequences within the cis-element are highly conserved compared with surrounding sequences. In addition, we have compared sequences around chloroplast editing sites and homologous sequences in species that lack an editing site due to the presence of a genomic T. Cis-elements for RNA editing sites are highly conserved in angiosperms; by contrast, comparable sequences around a genomically encoded T exhibit higher rates of nucleotide substitution, higher frequencies of indels, and greater ML distances. The loss in requirement for editing to create the ndhD start codon has resulted in the conversion of the PPR gene responsible for editing that site to a pseudogene. We show that organellar dependence on nuclear-encoded PPR proteins for gene expression has constrained the evolution of cis-elements that are required at the level of RNA processing. Thus, the expansion of the PPR gene family in plants has had a dramatic effect on the evolution of plant organelle genomes.

Editing site analysis in a gymnosperm mitochondrial genome reveals similarities with angiosperm mitochondrial genomes

Sequence analysis of organelle genomes and comprehensive analysis of C-to-U editing sites from flowering and non-flowering plants have provided extensive sequence information from diverse taxa. This study includes the first comprehensive analysis of RNA editing sites from a gymnosperm mitochondrial genome, and utilizes informatics analyses to determine conserved features in the RNA sequence context around editing sites. We have identified 565 editing sites in 21 full-length and 4 partial cDNAs of the 39 protein-coding genes identified from the mitochondrial genome of Cycas taitungensis. The information profiles and RNA sequence context of C-to-U editing sites in the Cycas genome exhibit similarity in the immediate flanking nucleotides. Relative entropy analyses indicate that similar regions in the 5' flanking 20 nucleotides have information content compared to angiosperm mitochondrial genomes. These results suggest that evolutionary constraints exist on the nucleotide sequences immediately adjacent to C-to-U editing sites, and similar regions are utilized in editing site recognition.

The ins and outs of editing and splicing of plastid RNAs: lessons from parasitic plants

In chloroplasts of higher plants, editing and splicing of transcripts is a prerequisite for the proper expression of the plastid genetic information and thereby for photosynthesis. Holoparasitic plants differ from photosynthetic plants in that they have abandoned a photoautotrophic life style, which has led to a reduction or loss of photosynthetic activity. The analysis of several parasitic plant plastid genomes revealed that coding capacities were reduced to different extent, encompassing genes that regulate plastid gene expression as well as photosynthesis genes. The reorganization of the plastid genome is also reflected in overall increases in point mutation rates that parallel the vanishing of RNA editing sites. Unprecedented in land plants is the parallel loss of the plastid gene coding for an intron maturase and all but one group IIa introns in two parasitic species. These observations highlight the plastome-wide effects that are associated with a relaxed evolutionary pressure in plants living a heterotrophic life style.

Loss of matK RNA editing in seed plant chloroplasts

Background

RNA editing in chloroplasts of angiosperms proceeds by C-to-U conversions at specific sites. Nuclear-encoded factors are required for the recognition of cis-elements located immediately upstream of editing sites. The ensemble of editing sites in a chloroplast genome differs widely between species, and editing sites are thought to evolve rapidly. However, large-scale analyses of the evolution of individual editing sites have not yet been undertaken.

Results

Here, we analyzed the evolution of two chloroplast editing sites, matK-2 and matK-3, for which DNA sequences from thousands of angiosperm species are available. Both sites are found in most major taxa, including deep-branching families such as the nymphaeaceae. However, 36 isolated taxa scattered across the entire tree lack a C at one of the two matK editing sites. Tests of several exemplary species from this in silico analysis of matK processing unexpectedly revealed that one of the two sites remain unedited in almost half of all species examined. A comparison of sequences between editors and non-editors showed that specific nucleotides co-evolve with the C at the matK editing sites, suggesting that these nucleotides are critical for editing-site recognition.

Conclusion

(i) Both matK editing sites were present in the common ancestor of all angiosperms and have been independently lost multiple times during angiosperm evolution.

(ii) The editing activities corresponding to matK-2 and matK-3 are unstable.

(iii) A small number of third-codon positions in the vicinity of editing sites are selectively constrained independent of the presence of the editing site, most likely because of interacting RNA-binding proteins.

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.

Post-transcriptional control of chloroplast gene expression

Chloroplasts contain their own genome, organized as operons, which are generally transcribed as polycistronic transcriptional units. These primary transcripts are processed into smaller RNAs, which are further modified to produce functional RNAs. The RNA processing mechanisms remain largely unknown and represent an important step in the control of chloroplast gene expression. Such mechanisms include RNA cleavage of pre-existing RNAs, RNA stabilization, intron splicing, and RNA editing. Recently, several nuclear-encoded proteins that participate in diverse plastid RNA processing events have been characterised. Many of them seem to belong to the pentatricopeptide repeat (PPR) protein family that is implicated in many crucial functions including organelle biogenesis and plant development. This review will provide an overview of current knowledge of the post-transcriptional processing in chloroplasts.