The grass subfamily Pooideae was studied using DNA sequence information from the chloroplast (cp) matK gene–3′trnK exon and the nuclear ribosomal (nr) ITS1–5.8S gene–ITS2 in a sample of 67 taxa covering all of its tribes. Branches with strong bootstrap support are consistently resolved in both datasets, whereas discrepancy is confined to low‐support or unsupported nodes in one of the datasets. The results do not reveal a significant role of past hybridisation, plastid lineage sorting or reticulation in the evolutionary diversification of the major lineages of the subfamily. The combined analysis of the plastid and nuclear datasets results in a largely well‐supported pattern of divergence for the major lineages of the subfamily. Some re‐alignments of tribes and subtribes are proposed and discussed with reference to relevant morphological and structural characters. We propose the recognition of broader tribes Nardeae with subtribes Nardinae and Lygeinae, Meliceae with subtribes Brylkiniinae and Melicinae, Stipeae with subtribes Ampelodesminae and Stipinae, and Triticeae with subtribes Littledaleinae, Brominae and Hordeinae. For the tribe complex of Aveneae and Poeae, the clear‐cut split into two major clades and further resolution into some high‐support lineages depicted by cpDNA is not contradicted by nuclear ITS and their taxonomic treatment as separate tribes or a single tribe remains an unanswered question.
To investigate the evolutionary diversification and morphological evolution of grass supertribe Poodae (subfam. Pooideae, Poaceae) we conducted a comprehensive molecular phylogenetic analysis including representatives from most of its accepted genera. We focused on generating a DNA sequence dataset of plastid matK gene-3′trnK exon and trnL-trnF regions and nuclear ribosomal (nr) ITS1-5.8S gene-ITS2 and ETS that was taxonomically overlapping as completely as possible (altogether 257 species). The idea was to infer whether phylogenetic trees or certain clades based on plastid and nrDNA data correspond with each other or discord, revealing signatures of past hybridization. The datasets were analysed separately, in combination, by excluding taxa with discordant placements in the individual gene trees and with duplication of these taxa in a way that each duplicate has only one data partition (plastid or nrDNA). We used maximum likelihood, maximum parsimony and Bayesian approaches. Instances of severe conflicts between the phylogenetic trees derived from both datasets, some of which have been noted earlier, point to hybrid origin of several lineages such as the ABCV clade encompassing several subtribes and subordinate clades,
Karyotype structures revealed by in situ hybridization with ribosomal and satellite DNAs and fluorochrome staining of AT- or GC-rich regions are reported for 23 diploid to tetraploid taxa of Aveneae genera Arrhenatherum, Avena, Helictotrichon, and Pseudarrhenatherum. Chromosomal features are compared with a molecular phylogeny generated on nuclear ribosomal (ITS, 5S) and chloroplast (matK) DNA sequences. Ancestral chromosomal character states are (1) two satellite chromosomes per set of x = 7, (2) 5S rDNA localized in nonsatellite chromosomes, (3) large chromosomes with (4) rather equal lengths of their respective chromosome arms, (5) sets with strong variance of chromosome lengths, (6) absence or small amounts of heterochromatin, and (7) absence or no detectable amplification of the satellite DNAs tested. Overall, most karyotype characteristics are species specific, but common patterns were found for the species of two large subgenera of Helictotrichon. Pseudarrhenatherum, although nested in the molecular phylogeny within Helictotrichon subgenus Helictotrichon, deviates strongly in karyotype characters such as Arrhenatherum as sister of Avena. The karyotype of Helictotrichon jahandiezii, sister to the clade of Helictotrichon subgenera Helictotrichon, Avena, and Arrhenatherum, strongly resembles that of Avena macrostachya. Karyotype features suggest that perennial A. macrostachya and H. jahandiezii are close to the C-genome species of annual Avena, whereas the Avena A genome resembles that of Arrhenatherum.
18To investigate the evolutionary diversification and morphological evolution of grass 19 supertribe Poodae (subfam. Pooideae, Poaceae) we conducted a comprehensive molecular 20 phylogenetic analysis including representatives from most of their accepted genera. We 21 focused on generating a DNA sequence dataset of plastid matK gene-3'trnK exon and trnL-22 trnF regions and nuclear ribosomal ITS1-5.8S gene-ITS2 and ETS that was taxonomically 23 overlapping as completely as possible (altogether 257 species). The idea was to infer whether 24 phylogenetic trees or certain clades based on plastid and nuclear DNA data correspond with 25 each other or discord, revealing signatures of past hybridization. The datasets were analysed 26 using maximum parsimony, maximum likelihood and Bayesian approaches. Instances of 27 severe conflicts between the phylogenetic trees derived from both datasets, some of which 28 have been noted earlier, unambiguously point to hybrid origin of several lineages (subtribes, 29 groups of genera, sometimes genera) such as Phalaridinae,
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