Exploring the plastid genome disparity of liverworts

Yu, Ying; Li, Hongmei; Yang, Jun‐Bo; Ma, Wei; Pressel, Silvia; Wu, Yuhuan; Schneider, Harald

doi:10.1111/jse.12515

Cited by 17 publications

(37 citation statements)

References 43 publications

(74 reference statements)

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“…The structural stability of liverwort mt genomes, in accordance with the remarkable structural conservatism of liverwort plastomes [40], might also be shaped by nuclear encoded DSBR proteins that suppress the error-prone ectopic recombinations across small direct repeats during DSBR in mitochondrion and plastid [41]. We here characterized six frequently reported DSBR gene families in the transcriptome assemblies of 125 land plant representatives (Additional file 11: Table S6).…”

Section: Resultsmentioning

confidence: 93%

Mitochondrial genomes of the early land plant lineage liverworts (Marchantiophyta): conserved genome structure, and ongoing low frequency recombination

et al. 2019

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Background: In contrast to the highly labile mitochondrial (mt) genomes of vascular plants, the architecture and composition of mt genomes within the main lineages of bryophytes appear stable and invariant. The available mt genomes of 18 liverwort accessions representing nine genera and five orders are syntenous except for Gymnomitrion concinnatum whose genome is characterized by two rearrangements. Here, we expanded the number of assembled liverwort mt genomes to 47, broadening the sampling to 31 genera and 10 orders spanning much of the phylogenetic breadth of liverworts to further test whether the evolution of the liverwort mitogenome is overall static. Results: Liverwort mt genomes range in size from 147 Kb in Jungermanniales (clade B) to 185 Kb in Marchantiopsida, mainly due to the size variation of intergenic spacers and number of introns. All newly assembled liverwort mt genomes hold a conserved set of genes, but vary considerably in their intron content. The loss of introns in liverwort mt genomes might be explained by localized retroprocessing events. Liverwort mt genomes are strictly syntenous in genome structure with no structural variant detected in our newly assembled mt genomes. However, by screening the paired-end reads, we do find rare cases of recombination, which means multiple concurrent genome structures may exist in the vegetative tissues of liverworts. Our phylogenetic analyses of the nuclear encoded double stand break repair protein families revealed liverwort-specific subfamilies expansions. Conclusions: The low repeat recombination level, selection, along with the intensified nuclear surveillance, might together shape the structural evolution of liverwort mt genomes.

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Section: Resultsmentioning

confidence: 93%

Mitochondrial genomes of the early land plant lineage liverworts (Marchantiophyta): conserved genome structure, and ongoing low frequency recombination

et al. 2019

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“…Geneious R11 11.0.5 (Biomatters Ltd, Auckland, New Zealand) was used for annotation based on S. ciliata chloroplast genome (NC_043786; Yu et al. 2019 ).…”

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confidence: 99%

The complete chloroplast genome of Scapania ampliata Steph., 1897 (Scapaniaceae, Jungermanniales)

Choi

Kwon²,

Park³

2020

Mitochondrial DNA Part B

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“…Organellar genomes of early land plants are known from their stable structure and almost identical gene order present in all main evolutionary lineages [1][2][3][4][5], which include complex thalloids, simply thalloids, leafy and early divergent leafy liverworts from the order Treubiales and Haplomitriales. Despite the fact that the organellar genomes of model liverwort Marchantia polymorpha were among first sequenced plant plastomes [6] and mitogenomes [7], the number of complete genomes sequences was very limited, till the end of the second decade of XXI century, when several paper were published significantly expanding our knowledge about evolutionary dynamics of these molecules [2][3][4][5]. The current genomic resources comprise 61 mitogenomes and 59 plastomes complete sequences, but many liverwort families do not have their representatives.…”

Section: Introductionmentioning

confidence: 99%

Sequencing of Organellar Genomes of Nowellia curvifolia (Cephaloziaceae Jungermanniales) Revealed the Smallest Plastome with Complete Gene Set and High Intraspecific Variation Suggesting Cryptic Speciation

et al. 2021

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The leafy liverwort Nowellia curvifolia is a widespread Holarctic species belonging to the family Cephaloziaceae. It is made up of a newly sequenced, assembled and annotated organellar genomes of two European specimens, which revealed the structure typical for liverworts, but also provided new insights into its microevolution. The plastome of N. curvifolia is the second smallest among photosynthetic liverworts, with the shortest known inverted repeats. Moreover, it is the smallest liverwort genome with a complete gene set, since two smaller genomes of Aneura mirabilis and Cololejeunea lanciloba are missing six and four protein-coding genes respectively. The reduction of plastome size in leafy liverworts seems to be mainly impacted by deletion within specific region between psbA and psbD genes. The comparative intraspecific analysis revealed single SNPs difference among European individuals and a low number of 35 mutations differentiating European and North American specimens. However, the genetic resources of Asian specimen enabled to identify 1335 SNPs in plastic protein-coding genes suggesting an advanced cryptic speciation within N. curvifolia or the presence of undescribed morphospecies in Asia. Newly sequenced mitogenomes from European specimens revealed identical gene content and structure to previously published and low intercontinental differentiation limited to one substitution and three indels. The RNA-seq based RNA editing analysis revealed 17 and 127 edited sites in plastome and mitogenome respectively including one non-canonical editing event in plastid chiL gene. The U to C editing is common in non-seed plants, but in liverwort plastome is reported for the first time.

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Exploring the plastid genome disparity of liverworts

Cited by 17 publications

References 43 publications

Mitochondrial genomes of the early land plant lineage liverworts (Marchantiophyta): conserved genome structure, and ongoing low frequency recombination

Mitochondrial genomes of the early land plant lineage liverworts (Marchantiophyta): conserved genome structure, and ongoing low frequency recombination

The complete chloroplast genome of Scapania ampliata Steph., 1897 (Scapaniaceae, Jungermanniales)

Sequencing of Organellar Genomes of Nowellia curvifolia (Cephaloziaceae Jungermanniales) Revealed the Smallest Plastome with Complete Gene Set and High Intraspecific Variation Suggesting Cryptic Speciation

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