Plastome phylogenomic analysis reveals evolutionary divergences of Polypodiales suborder Dennstaedtiineae [PDF]
BMC Plant Biology, 2022 Background Polypodiales suborder Dennstaedtiineae contain a single family Dennstaedtiaceae, eleven genera, and about 270 species, and include some groups that were previously placed in Dennstaedtiaceae, Hypolepidaceae, Monachosoraceae, and Pteridaceae ...
Li-Yaung Kuo +2 more
exaly +5 more sources
Lepisorus medioximus (Polypodiales, Polypodiaceae), a new species from Shan State of Myanmar [PDF]
PhytoKeys, 2022 A new species of the species-rich fern genus Lepisorus (Polypodiales, Polypodiaceae) has been found to occur in Shan state, Myanmar. Lepisorus medioximus is described based on morphological characters and phylogenetic evidence.
Tao Fujiwara +5 more
doaj +6 more sources
Documenting the Sporangium Development of the Polypodiales Fern Pteris multifida [PDF]
Frontiers in Plant Science, 2022 Reconstructing the development of sporangia in seed-free vascular plants provides crucial information about key processes enabling the production of spores that are important in the life cycle of these plants.
Nai-Ying Yang +6 more
doaj +4 more sources
Diplazium clivicolum (Polypodiales, Athyriaceae), a new fern species from southern Yunnan, China [PDF]
PhytoKeysA new species in Athyriaceae, Diplazium clivicolum (section Anisogonium) is described and illustrated from southern Yunnan, China. Diplazium clivicolum exhibits the greatest morphological similarity to D.
Hong-Jin Wei, Zheng-Yu Zuo
doaj +6 more sources
Organelle Genome Inheritance in Deparia Ferns (Athyriaceae, Aspleniineae, Polypodiales) [PDF]
Frontiers in Plant Science, 2018 Organelle genomes of land plants are predominately inherited maternally but in some cases can also be transmitted paternally or biparentally. Compared to seed plants (>83% genera of angiosperms and >12% genera of gymnosperms), plastid genome ...
Li-Yaung Kuo, Fay-Wei Li, Huei-Jiun Su
exaly +5 more sources
BMC Plant Biology, 2017 Background Ferns are large and underexplored group of vascular plants (~ 11 thousands species). The genomic data available by now include low coverage nuclear genomes sequences and partial sequences of mitochondrial genomes for six species and several ...
Kamil Khafizov +2 more
exaly +5 more sources
Phylotranscriptomics Illuminates the Placement of Whole Genome Duplications and Gene Retention in Ferns [PDF]
Frontiers in Plant Science, 2022 Ferns are the second largest clade of vascular plants with over 10,000 species, yet the generation of genomic resources for the group has lagged behind other major clades of plants.
Jessie A. Pelosi +4 more
doaj +2 more sources
The complete chloroplast genome of the fern Asplenium tenerum (Aspleniaceae) [PDF]
Mitochondrial DNA. Part B. Resources, 2020 Plastid genomes are useful markers in resolving plant phylogenetic relationships for various taxonomic groups. Here, we sequenced and de novo assembled the complete plastid genome sequence of the fern Asplenium tenerum Forst. (Aspleniaceae, Polypodiales)
Yang Peng +3 more
doaj +2 more sources
Diversity and host plant utilization of leaf-mining beetles of Chrysomeloidea (Coleoptera) in Japan [PDF]
ZooKeysThe superfamily Chrysomeloidea (Cerambycidae + Chrysomelidae + Megalopodidae) encompasses a diverse phytophagous beetles, whose larvae exhibit internal or external feeding on leaves, wood, or roots of many plants.
Makoto Kato, Yume Imada
doaj +4 more sources
Subgenome evolutionary dynamics in allotetraploid ferns: insights from the gene expression patterns in the allotetraploid species Phegopteris decursivepinnata (Thelypteridaceae, Polypodiales) [PDF]
Frontiers in Plant Science, 2023 Allopolyploidization often leads to disruptive conflicts among more than two sets of subgenomes, leading to genomic modifications and changes in gene expression.
Natsu Katayama +5 more
doaj +2 more sources