REDIdb: an upgraded bioinformatics resource for organellar RNA editing sites.

RNA editing is a post-transcriptional molecular process whereby the information in a genetic message is modified from that in the corresponding DNA template by means of nucleotide substitutions, insertions and/or deletions. It occurs mostly in organelles by clade-specific diverse and unrelated biochemical mechanisms. RNA editing events have been annotated in primary databases as GenBank and at more sophisticated level in the specialized databases REDIdb, dbRES and EdRNA. At present, REDIdb is the only freely available database that focuses on the organellar RNA editing process and annotates each editing modification in its biological context. Here we present an updated and upgraded release of REDIdb with a web-interface refurbished with graphical and computational facilities that improve RNA editing investigations. Details of the REDIdb features and novelties are illustrated and compared to other RNA editing databases. REDIdb is freely queried at http://biologia.unical.it/py_script/REDIdb/.

Lineage-specific group II intron gains and losses of the mitochondrial rps3 gene in gymnosperms.

According to PCR assays and sequencing, we now report the shared presence of two rps3 introns, namely the rps3i74 and the rps3i249, in the mitochondria of all the classes representing the surviving lineages of gymnosperms, and unveil several lineages experiencing intron loss. Interestingly, the rps3 intron gains and losses within the four groups of gymnosperms let us sort out the Pinaceae and the non-Pinaceae into intron (+)- and intron (-)-lineages, respectively. Worthy of mention is also the finding that only Gnetum within the Gnetales harbours both the rps3 introns. This intron distribution pattern is consistent with the hypothesis that the two rps3 introns were likely present in the common ancestor of the seed plants and, then, independently lost in the non-Pinaceae during gymnosperm evolution. The derived secondary structural model of the novel group IIA intron improves our understanding of the significance and origin of the extraordinary length polymorphisms observed among rps3i249 orthologs. Despite the remarkable structural plasticity to adopt and reject introns, the rps3 mRNAs undergo accurate processing by splicing and extensive editing in gymnosperm mitochondria. This study provides additional insights into the evolutionarily high dynamics of mitochondrial introns which may come and go in closely related plant species. The turnover of the mitochondrial rps3 group II introns seen among lineages of seed plants further suggests that these introns might be an additional signature to discriminate between particularly cryptical taxonomic groups for which there is a need of a further evaluation of their evolutionary affiliation.

Mapping of 5' and 3'-ends of sunflower mitochondrial nad6 mRNAs reveals a very complex transcription pattern which includes primary transcripts lacking 5'-UTR.

Nad6 orf, encoded in the sunflower mitochondrial genome in single copy contains a non-conserved 3'-extension. The transcription of the nad6 locus generates a highly complex pattern. Three main transcripts of 1240, 960 and 870 nt have been characterized by different approaches. The two smaller ones are apparently the most abundant of the steady-state RNA population and are generated as primary transcription products as well as by processing of the 1240 nt transcript. Their 5'-UTRs are absent or very short. Whereas the 3'-ends of the 960 nt transcripts contain a TGA codon the shorter one terminates at positions excluding the stop codon. The fate of transcripts to promote the synthesis of NAD6 sunflower protein seems, thus, to rely on the occurrence of mechanisms yet to be identified.

Is plant mitochondrial RNA editing a source of phylogenetic incongruence? An answer from in silico and in vivo data sets.

BACKGROUND: In plant mitochondria, the post-transcriptional RNA editing process converts C to U at a number of specific sites of the mRNA sequence and usually restores phylogenetically conserved codons and the encoded amino acid residues. Sites undergoing RNA editing evolve at a higher rate than sites not modified by the process. As a result, editing sites strongly affect the evolution of plant mitochondrial genomes, representing an important source of sequence variability and potentially informative characters. To date no clear and convincing evidence has established whether or not editing sites really affect the topology of reconstructed phylogenetic trees. For this reason, we investigated here the effect of RNA editing on the tree building process of twenty different plant mitochondrial gene sequences and by means of computer simulations. RESULTS: Based on our simulation study we suggest that the editing 'noise' in tree topology inference is mainly manifested at the cDNA level. In particular, editing sites tend to confuse tree topologies when artificial genomic and cDNA sequences are generated shorter than 500 bp and with an editing percentage higher than 5.0%. Similar results have been also obtained with genuine plant mitochondrial genes. In this latter instance, indeed, the topology incongruence increases when the editing percentage goes up from about 3.0 to 14.0%. However, when the average gene length is higher than 1,000 bp (rps3, matR and atp1) no differences in the comparison between inferred genomic and cDNA topologies could be detected. CONCLUSIONS: Our findings by the here reported in silico and in vivo computer simulation system seem to strongly suggest that editing sites contribute in the generation of misleading phylogenetic trees if the analyzed mitochondrial gene sequence is highly edited (higher than 3.0%) and reduced in length (shorter than 500 bp). In the current lack of direct experimental evidence the results presented here encourage, thus, the use of genomic mitochondrial rather than cDNA sequences for reconstructing phylogenetic events in land plants.

REDIdb: the RNA editing database.

The RNA Editing Database (REDIdb) is an interactive, web-based database created and designed with the aim to allocate RNA editing events such as substitutions, insertions and deletions occurring in a wide range of organisms. The database contains both fully and partially sequenced DNA molecules for which editing information is available either by experimental inspection (in vitro) or by computational detection (in silico). Each record of REDIdb is organized in a specific flat-file containing a description of the main characteristics of the entry, a feature table with the editing events and related details and a sequence zone with both the genomic sequence and the corresponding edited transcript. REDIdb is a relational database in which the browsing and identification of editing sites has been simplified by means of two facilities to either graphically display genomic or cDNA sequences or to show the corresponding alignment. In both cases, all editing sites are highlighted in colour and their relative positions are detailed by mousing over. New editing positions can be directly submitted to REDIdb after a user-specific registration to obtain authorized secure access. This first version of REDIdb database stores 9964 editing events and can be freely queried at http://biologia.unical.it/py_script/search.html.

EdiPy: a resource to simulate the evolution of plant mitochondrial genes under the RNA editing.

EdiPy is an online resource appropriately designed to simulate the evolution of plant mitochondrial genes in a biologically realistic fashion. EdiPy takes into account the presence of sites subjected to RNA editing and provides multiple artificial alignments corresponding to both genomic and cDNA sequences. Each artificial data set can successively be submitted to main and widespread evolutionary and phylogenetic software packages such as PAUP, Phyml, PAML and Phylip. As an online bioinformatic resource, EdiPy is available at the following web page: http://biologia.unical.it/py_script/index.html.

A novel additional group II intron distinguishes the mitochondrial rps3 gene in gymnosperms.

Comparative analysis of the ribosomal protein S3 gene (rps3) in the mitochondrial genome of Cycas with newly sequenced counterparts from Magnolia and Helianthus and available sequences from higher plants revealed that the positional clustering with the genes for ribosomal protein S19 (rps19) and L16 (rpl16) is preserved in gymnosperms. However, in contrast to the other land plant species, the rps3 gene in Cycas mitochondria is unique in possessing a second intron: rps3i2. Reverse transcription-polymerase chain reaction (RT-PCR) analysis of the transcripts generated from the rps19-rps3-rpl16 cluster in Cycas mitochondria demonstrated that the genes are cotranscribed and extensively modified by RNA editing and that both introns are efficiently spliced. Despite remarkable size heterogeneity, the Cycas rps3i1 can be shown to be homologous to the group IIA introns present within the rps3 gene of algae and land plants, including Magnolia and Helianthus. Conversely, sequences similar to the rps3i2 have not been reported previously. On the basis of conserved primary and secondary structure the second intervening sequence interrupting the Cycas rps3 gene has been classified as a group II intron. The close relationship of the rps3i2 to a group of different plant mitochondrial introns is intriguing and suggestive of a mitochondrial derivation for this novel intervening sequence. Interestingly, the rps3i2 appears to be conserved at the same gene location in other gymnosperms. Furthermore, the pattern of the rps3i2 distribution among algae and land plants provides evidence for the evolutionary acquisition of this novel intron in gymnosperms via intragenomic transposition or retrotransposition.

Striking differences in RNA editing requirements to express the rps4 gene in magnolia and sunflower mitochondria.

The ribosomal protein S4 gene (rps4) has been identified as a single copy sequence in the mitochondrial genomes of two distant higher plants, Magnolia and Helianthus. Sequence analysis revealed that the rps4 genes present in the magnolia and sunflower mitochondrial genomes encode S4 polypeptides of 352 and 331 amino acids, respectively, longer than their counterparts in liverwort and bacteria. Expression of the rps4 genes in the investigated higher plant mitochondria was confirmed by Western blot analysis. In Helianthus, one of two short nucleotide insertions at the 3'-end introduces in the coding region a premature termination codon. Northern hybridizations and reverse transcription-polymerase chain reaction analysis demonstrated that the monocistronic RNA transcripts generated from the rps4 locus in Magnolia and Helianthus mitochondria are modified by RNA editing at 28 and 13 positions, respectively. Although evolutionarily conserved, RNA editing requirements of the rps4 appear more extensive in Magnolia than in Helianthus and in the other higher plants so far investigated. Furthermore, our analysis also suggests that selection of editing sites is RNA sequence-specific in a duplicated sequence context.