RNA Editing in Chloroplasts

Substantial structural variation and repetitive DNA content contribute to intraspecific plastid genome evolution

BACKGROUND

Plastids have highly conserved genomes in most land plants. However, in several families, plastid genomes exhibit high rates of nucleotide substitution and structural rearrangements among species. This elevated rate of evolution has been posited to lead to increased rates of plastid-nuclear incompatibilities (PNI), potentially acting as a driver of speciation. However, the extent to which plastid structural variation exists within a species is unknown. This study investigates whether plastid structural variation, observed at the interspecific level in Campanulaceae, also occurs within Campanula americana, a species with strong intraspecific PNI. We assembled multiple plastid genomes from three lineages of C. americana that exhibit varying levels of PNI when crossed. We then investigated the structural variation and repetitive DNA content among these lineages and compared the repetitive DNA content with that of other species within the family.

RESULTS

We found significant variation in plastid genome size among the lineages of C. americana (188,309-201,788 bp). This variation was due in part to multiple gene duplications in the inverted repeat region. Lineages also varied in their repetitive DNA content, with the Appalachian lineage displaying the highest proportion of tandem repeats (~ 10%) compared to the Eastern and Western lineages (~ 6%). In addition, genes involved in transcription and protein transport showed elevated sequence divergence between lineages, and a strong correlation was observed between genome size and repetitive DNA content. Campanula americana was found to have one of the most repetitive plastid genomes within Campanulaceae.

CONCLUSIONS

These findings challenge the conventional view of plastid genome conservation within a species and suggest that structural variation, differences in repetitive DNA content, and divergence of key genes involved in transcription and protein transport may play a role in PNI. This study highlights the need for further research into the genetic mechanisms underlying PNI, a key process in the early stages of speciation.

Plastid mRNA translation

Overall translational machinery in plastids is similar to that of E. coli. Initiation is the crucial step for translation and this step in plastids is somewhat different from that of E. coli. Unlike the Shine-Dalgarno sequence in E. coli, cis-elements for translation initiation are not well conserved in plastid mRNAs. Specific trans-acting factors are generally required for translation initiation and its regulation in plastids. During translation elongation, ribosomes pause sometimes on photosynthesis-related mRNAs due probably to proper insertion of nascent polypeptides into membrane complexes. Codon usage of plastid mRNAs is different from that of E. coli and mammalian cells. Plastid mRNAs do not have the so-called rare codons. Translation efficiencies of several synonymous codons are not always correlated with codon usage in plastid mRNAs.

The evolution of chloroplast genes and genomes in ferns

Most of the publicly available data on chloroplast (plastid) genes and genomes come from seed plants, with relatively little information from their sister group, the ferns. Here we describe several broad evolutionary patterns and processes in fern plastid genomes (plastomes), and we include some new plastome sequence data. We review what we know about the evolutionary history of plastome structure across the fern phylogeny and we compare plastome organization and patterns of evolution in ferns to those in seed plants. A large clade of ferns is characterized by a plastome that has been reorganized with respect to the ancestral gene order (a similar order that is ancestral in seed plants). We review the sequence of inversions that gave rise to this organization. We also explore global nucleotide substitution patterns in ferns versus those found in seed plants across plastid genes, and we review the high levels of RNA editing observed in fern plastomes.

Chloroplast RNA metabolism

The chloroplast genome encodes proteins required for photosynthesis, gene expression, and other essential organellar functions. Derived from a cyanobacterial ancestor, the chloroplast combines prokaryotic and eukaryotic features of gene expression and is regulated by many nucleus-encoded proteins. This review covers four major chloroplast posttranscriptional processes: RNA processing, editing, splicing, and turnover. RNA processing includes the generation of transcript 5' and 3' termini, as well as the cleavage of polycistronic transcripts. Editing converts specific C residues to U and often changes the amino acid that is specified by the edited codon. Chloroplasts feature introns of groups I and II, which undergo protein-facilitated cis- or trans-splicing in vivo. Each of these RNA-based processes involves proteins of the pentatricopeptide motif-containing family, which does not occur in prokaryotes. Plant-specific RNA-binding proteins may underpin the adaptation of the chloroplast to the eukaryotic context.