Rickettsial DNA invasions and a scrambled rRNA cluster with 
a trans-splicing group I intron: The highly unorthodox mitogenome 
of the fern Haplopteris ensiformis

Zumkeller, Simon; Polsakiewicz, Monika; Knoop, Volker

doi:10.21203/rs.3.rs-2152556/v1

“…Since the early days of molecular systematics, molecular phylogenetic studies in land plants have heavily relied on the plastid genome (plastome), due to its high copy number and more stable structure compared to the other two genomes (mitogenome and nuclear genome) (Zardoya 2020). Thanks to the high-throughput sequencing techniques, studies using the other two genomes have recently become more common, resulting in improved understanding of the evolution of plants and their genomes (e.g., Guo et al 2016, Jackman et al 2020, Kan et al 2020, Sullivan et al 2020, Zardoya 2020, Feng & Wicke 2023, Zumkeller et al 2023. Whereas the plastome is structurally rather conserved, the plant mitogenome varies greatly in size, gene structure, mutation rate, and level of RNA editing, hampering its assembly and use in phylogenetic studies (Ogihara et al 2005, Richardson et al 2013, Bonavita & Rosaria 2016, Small et al 2020, Zardoya 2020, Zumkeller et al 2023.…”

Section: Introductionmentioning

confidence: 99%

“…Thanks to the high-throughput sequencing techniques, studies using the other two genomes have recently become more common, resulting in improved understanding of the evolution of plants and their genomes (e.g., Guo et al 2016, Jackman et al 2020, Kan et al 2020, Sullivan et al 2020, Zardoya 2020, Feng & Wicke 2023, Zumkeller et al 2023. Whereas the plastome is structurally rather conserved, the plant mitogenome varies greatly in size, gene structure, mutation rate, and level of RNA editing, hampering its assembly and use in phylogenetic studies (Ogihara et al 2005, Richardson et al 2013, Bonavita & Rosaria 2016, Small et al 2020, Zardoya 2020, Zumkeller et al 2023. Despite the highly variable structure of plant mitogenomes, it has been broadly demonstrated that mitochondrial genes in flowering plants have lower substitution rates than plastid genes (Wolfe et al 1987, Palmer & Herbon 1988, Cho et al 2004, Parkinson et al 2005, Richardson et al 2013, and that some species seem to have practically frozen mitogenome (Richardson et al 2013).…”

Section: Introductionmentioning

confidence: 99%

Untitled

2023

Phytotaxa

0

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The current understanding of fern phylogeny is primarily based on plastid and nuclear sequences, but the third genome-the mitogenome-has remained practically unstudied. We inferred the first broad scale fern phylogeny based on mitogenomic data, obtained from the One Thousand Plant Transcriptomes Initiative project, and compared it with the plastid phylogeny. The trees were mostly congruent and corresponded to the current understanding of the fern phylogeny, but we observed different evolutionary patterns between the two genomes. Protein-coding markers located in the plastome had, on average, over two times higher substitution rate than the markers from the mitogenome. The similar rate variation pattern between the genomes in different fern lineages supports the idea that a common mechanism, like life history traits, drives the rates of molecular evolution. The few conflicting nodes we observed have also been difficult to resolve in other studies, suggesting that even genomic data may not suffice to resolve them.

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“…Since the early days of molecular systematics, molecular phylogenetic studies in land plants have heavily relied on the plastid genome (plastome), due to its high copy number and more stable structure compared to the other two genomes (mitogenome and nuclear genome) (Zardoya 2020). Thanks to the high-throughput sequencing techniques, studies using the other two genomes have recently become more common, resulting in improved understanding of the evolution of plants and their genomes (e.g., Guo et al 2016, Jackman et al 2020, Kan et al 2020, Sullivan et al 2020, Zardoya 2020, Feng & Wicke 2023, Zumkeller et al 2023. Whereas the plastome is structurally rather conserved, the plant mitogenome varies greatly in size, gene structure, mutation rate, and level of RNA editing, hampering its assembly and use in phylogenetic studies (Ogihara et al 2005, Richardson et al 2013, Bonavita & Rosaria 2016, Small et al 2020, Zardoya 2020, Zumkeller et al 2023.…”

Section: Introductionmentioning

confidence: 99%

“…Thanks to the high-throughput sequencing techniques, studies using the other two genomes have recently become more common, resulting in improved understanding of the evolution of plants and their genomes (e.g., Guo et al 2016, Jackman et al 2020, Kan et al 2020, Sullivan et al 2020, Zardoya 2020, Feng & Wicke 2023, Zumkeller et al 2023. Whereas the plastome is structurally rather conserved, the plant mitogenome varies greatly in size, gene structure, mutation rate, and level of RNA editing, hampering its assembly and use in phylogenetic studies (Ogihara et al 2005, Richardson et al 2013, Bonavita & Rosaria 2016, Small et al 2020, Zardoya 2020, Zumkeller et al 2023. Despite the highly variable structure of plant mitogenomes, it has been broadly demonstrated that mitochondrial genes in flowering plants have lower substitution rates than plastid genes (Wolfe et al 1987, Palmer & Herbon 1988, Cho et al 2004, Parkinson et al 2005, Richardson et al 2013, and that some species seem to have practically frozen mitogenome (Richardson et al 2013).…”

Section: Introductionmentioning

confidence: 99%

The third opinion on fern phylogenetics with novel insights into their mitogenome evolution

CÁRDENAS,

LEHTONEN

2023

Phytotaxa

1

0

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The current understanding of fern phylogeny is primarily based on plastid and nuclear sequences, but the third genome—the mitogenome—has remained practically unstudied. We inferred the first broad scale fern phylogeny based on mitogenomic data, obtained from the One Thousand Plant Transcriptomes Initiative project, and compared it with the plastid phylogeny. The trees were mostly congruent and corresponded to the current understanding of the fern phylogeny, but we observed different evolutionary patterns between the two genomes. Protein-coding markers located in the plastome had, on average, over two times higher substitution rate than the markers from the mitogenome. The similar rate variation pattern between the genomes in different fern lineages supports the idea that a common mechanism, like life history traits, drives the rates of molecular evolution. The few conflicting nodes we observed have also been difficult to resolve in other studies, suggesting that even genomic data may not suffice to resolve them.

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Categorizing 161 plant (streptophyte) mitochondrial group II introns into 29 families of related paralogues finds only limited links between intron mobility and intron-borne maturases

Zumkeller

¹

,

Knoop

²

2023

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Group II introns are common in the two endosymbiotic organelle genomes of the plant lineage. Chloroplasts harbor 22 positionally conserved group II introns whereas their occurrence in land plant (embryophyte) mitogenomes is highly variable and specific for the seven major clades: liverworts, mosses, hornworts, lycophytes, ferns, gymnosperms and flowering plants. Each plant group features “signature selections” of ca. 20–30 paralogues from a superset of altogether 105 group II introns meantime identified in embryophyte mtDNAs, suggesting massive intron gains and losses along the backbone of plant phylogeny. We report on systematically categorizing plant mitochondrial group II introns into “families”, comprising evidently related paralogues at different insertion sites, which may even be more similar than their respective orthologues in phylogenetically distant taxa. Including streptophyte (charophyte) algae extends our sampling to 161 and we sort 104 streptophyte mitochondrial group II introns into 25 core families of related paralogues evidently arising from retrotransposition events. Adding to discoveries of only recently created intron paralogues, hypermobile introns and twintrons, our survey led to further discoveries including previously overlooked “fossil” introns in spacer regions or e.g., in the rps8 pseudogene of lycophytes. Initially excluding intron-borne maturase sequences for family categorization, we added an independent analysis of maturase phylogenies and find a surprising incongruence between intron mobility and the presence of intron-borne maturases. Intriguingly, however, we find that several examples of nuclear splicing factors meantime characterized simultaneously facilitate splicing of independent paralogues now placed into the same intron families. Altogether this suggests that plant group II intron mobility, in contrast to their bacterial counterparts, is not intimately linked to intron-encoded maturases.

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Rickettsial DNA invasions and a scrambled rRNA cluster with a trans-splicing group I intron: The highly unorthodox mitogenome of the fern Haplopteris ensiformis

Cited by 3 publications

References 86 publications

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The third opinion on fern phylogenetics with novel insights into their mitogenome evolution

Categorizing 161 plant (streptophyte) mitochondrial group II introns into 29 families of related paralogues finds only limited links between intron mobility and intron-borne maturases

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