Olaf Malek

The fragmentation of group II introns without concomitant loss of splicing competence is illustrated by extraordinary gene arrangements in plant mitochondrial genomes. The mitochondrial genes nad1, nad2, and nad5, all encoding subunits of the NADH dehydrogenase, require trans-splicing for functional assembly of their mRNAs in flowering plants. Tracing the origins of trans-splicing group II introns shows that they have evolved from formerly cis-arranged homologs whose descendants can still be identified in lineages of early branching land plants. In this contribution we present the full set of ancestor introns for all five conserved mitochondrial trans-splicing positions. These introns are strikingly small in the quillwort Isoetes lacustris, the continuous nad2 gene intron in this species representing the smallest (389 nt) land plant group II intron yet identified. cDNA analysis shows correct splicing of the introns in vivo and also identifies frequent RNA editing events in the flanking nad gene exons. Other representatives of the ancestral cis-arranged introns are identified in the fern Osmunda regalis, the horsetail Equisetum telmateia, and the hornwort Anthoceros crispulus. Only the now identified intron in Osmunda carries significant traces of a former maturase reading frame. The identification of a continuous homolog in Anthoceros demonstrates that intron invasion into the affected genes in some cases predated the split of vascular and nonvascular plants more than 400 million years ago. As an alternative to disruption after size increase, the respective introns can get secondarily lost in certain lineages.

Trans-splicing in angiosperm plant mitochondria connects exons from independent RNA molecules by means of group II intron fragments. Homologues of trans-splicing introns in the angiosperm mitochondrial nad2 and nad5 genes are now identified as uninterrupted group II introns in the ferns Asplenium nidus and Marsilea drummondii. These fern introns are correctly spliced from the pre-mRNA at the sites predicted from their well-conserved secondary structures. The flanking exon sequences of the nad2 and nad5 genes in the ferns require RNA editing, including the removal of in-frame stop codons by U-to-C changes for correct expression of the genetic information. We conclude that cis-splicing introns like the ones now identified in ferns are the ancestors of trans-splicing introns in angiosperm mitochondria. Intron disruption is apparently due to a size increase of the structurally variable group II intron domain IV followed by DNA recombination in the plant mitochondrial genome.