The Phylogenetic Position of the Enigmatic, Polypodium hydriforme (Cnidaria, Polypodiozoa): Insights from Mitochondrial Genomes.

Polypodium hydriforme is an enigmatic parasite that belongs to the phylum Cnidaria. Its taxonomic position has been debated: whereas it was previously suggested to be part of Medusozoa, recent phylogenomic analyses based on nuclear genes support the view that P. hydriforme and Myxozoa form a clade called Endocnidozoa. Medusozoans have linear mitochondrial (mt) chromosomes, whereas myxozoans, as most metazoan species, have circular chromosomes. In this work, we determined the structure of the mt genome of P. hydriforme, using Illumina and Oxford Nanopore Technologies reads, and showed that it is circular. This suggests that P. hydriforme is not nested within Medusozoa, as this would entail linearization followed by recirculation. Instead, our results support the view that P. hydriforme is a sister clade to Myxozoa, and mt linearization in the lineage leading to medusozoans occurred after the divergence of Myxozoa + P. hydriforme. Detailed analyses of the assembled P. hydriforme mt genome show that: (1) it is encoded on a single circular chromosome with an estimated size of ∼93,000 base pairs, making it one of the largest metazoan mt genomes; (2) around 78% of the genome encompasses a noncoding region composed of several repeat types; (3) similar to Myxozoa, no mt tRNAs were identified; (4) the codon TGA is a stop codon and does not encode for tryptophan as in other cnidarians; (5) similar to myxozoan mt genomes, it is extremely fast evolving.

Evidence for reciprocal origins in Polypodium hesperium (Polypodiaceae): a fern model system for investigating how multiple origins shape allopolyploid genomes.

UNLABELLED: • PREMISE OF THE STUDY: Many polyploid species are composed of distinct lineages originating from multiple, independent polyploidization events. In the case of allopolyploids, reciprocal crosses between the same progenitor species can yield lineages with different uniparentally inherited plastid genomes. While likely common, there are few well-documented examples of such reciprocal origins. Here we examine a case of reciprocal allopolyploid origins in the fern Polypodium hesperium and present it as a natural model system for investigating the evolutionary potential of duplicated genomes.• METHODS: Using a combination of uniparentally inherited plastid and biparentally inherited nuclear sequence data, we investigated the distributions and relative ages of reciprocally formed lineages in Polypodium hesperium, an allotetraploid fern that is broadly distributed in western North America.• KEY RESULTS: The reciprocally derived plastid haplotypes of Polypodium hesperium are allopatric, with populations north and south of 42°N latitude having different plastid genomes. Incorporating biogeographic information and previously estimated ages for the diversification of its diploid progenitors, we estimate middle to late Pleistocene origins of P. hesperium.• CONCLUSIONS: Several features of Polypodium hesperium make it a particularly promising system for investigating the evolutionary consequences of allopolyploidy. These include reciprocally derived lineages with disjunct geographic distributions, recent time of origin, and extant diploid progenitors.

RNA editing restores critical domains of a group I intron in fern mitochondria.

In the leptosporangiate fern Osmunda regalis, cox1 gene is disrupted by a 1071-nucleotide-long group I intron that is homologous to the Marchantia polymorpha cox1 intron 4 (cox1i395g1). This intron, which shares 89% sequence identity with its bryophyte counterpart, lost the capacity to encode for a maturase due to insertion/deletion mutations. The cox1 coding region is interrupted by a stop codon in both exons. The cox1 transcript undergoes 58 C-to-U and 13 U-to-C conversions, including the suppression of two stop codons that result in the recovery of a functional cox1 ORF. Interestingly, 4 C-to-U conversions found in mRNA precursors showed that the O. regalis cox1i395g1 intron is efficiently edited. These modifications improved the sequence identity with the Marchantia cox1i395 intron. In particular, the RNA editing events affect regions involved in secondary and tertiary structures of the intron, restoring three base pairing in the structural P5a and P9 helices, and correcting a highly conserved U in the P7 helix that contributes to the catalytic core. Moreover, cox1 intron orthologous from three different fern species were found to be edited by both C-to-U and U-to-C conversions in P7 and P9. Thus, RNA editing helps to correct the conserved domains of group I introns in "true ferns", suggesting a possible link between editing and splicing. We present here the first experimental evidence of RNA editing concerning a group I intron in plant organelles.