Conny Bruun Asmussen Lange scite author profile

Supertree and supermatrix methods have great potential in the quest to build the tree of life and yet they remain controversial, with most workers opting for one approach or the other, but rarely both. Here, we employed both methods to construct phylogenetic trees of all genera of palms (Arecaceae/Palmae), an iconic angiosperm family of great economic importance. We assembled a supermatrix consisting of 16 partitions, comprising DNA sequence data, plastid restriction fragment length polymorphism data, and morphological data for all genera, from which a highly resolved and well-supported phylogenetic tree was built despite abundant missing data. To construct supertrees, we used variants of matrix representation with parsimony (MRP) analysis based on input trees generated directly from subsamples of the supermatrix. All supertrees were highly resolved. Standard MRP with bootstrap-weighted matrix elements performed most effectively in this case, generating trees with the greatest congruence with the supermatrix tree and fewest clades unsupported by any input tree. Nonindependence due to input trees based on combinations of data partitions was an acceptable trade-off for improvements in supertree performance. Irreversible MRP and the use of strictly independent input trees only provided no obvious benefits. Contrary to previous claims, we found that unsupported clades are not infrequent under some MRP implementations, with up to 13% of clades lacking support from any input tree in some irreversible MRP supertrees. To build a formal synthesis, we assessed the cross-corroboration between supermatrix trees and the variant supertrees using semistrict consensus, enumerating shared clades and compatible clades. The semistrict consensus of the supermatrix tree and the most congruent supertree contained 160 clades (of a maximum of 204), 137 of which were present in both trees. The relationships recovered by these trees strongly support the current phylogenetic classification of palms. We evaluate 2 composite supertree support measures (rQS and V) and conclude that it is more informative to report numbers of input trees that support or conflict with a given supertree clade. This study demonstrates that supertree and supermatrix methods can provide effective, explicit, and complimentary mechanisms for synthesizing disjointed phylogenetic evidence while emphasizing the need for further refinement of supertree methods.

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Mid-Tertiary dispersal, not Gondwanan vicariance explains distribution patterns in the wax palm subfamily (Ceroxyloideae: Arecaceae)

Trénel

Hellström

Baker

et al. 2007

Molecular Phylogenetics and Evolution

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Phylogeny and divergence times of Bactridinae (Arecaceae, Palmae) based on plastid and nuclear DNA sequences

Eiserhardt

Pintaud

Lange

et al. 2011

TAXON

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Bactridinae include about 150 species of spiny Neotropical palms in five genera that are ecologically important in several vegetation types such as open woodland (Acrocomia), lowland rainforest (Astrocaryum, Bactris), and montane forest (Aiphaness). The subtribe also includes the only exclusively lianescent palm genus in the Neotropics (Desmoncus). We present a fully resolved molecular phylogeny of 41 species of Bactridinae, representing all genera as well as most of the currently ac ‐ cepted infrageneric taxa (subgenera, sections etc.) and recently proposed informal groups. Analyses are based on five plastid DNA regions (matK, trnQ‐rps16, rps16 intron, trnD‐trnT, trnL‐trnF) and three nuclear markers (PRK, RPB2, ITS). A combined dataset was analysed with likelihood and parsimony methods. The results show that all accepted taxa at and above the generic level are monophyletic with high support. Astrocaryum alatum and A. mexicanum, recently segregated into a genus of their own (Hexopetion), form a strongly supported monophyletic group sister to the remaining Astrocaryum species. Desmoncus and Acrocomia are resolved as sister genera, and together they are sister to the remaining Bactridinae. This finding contrasts with that of two previous studies reporting Acrocomia to be sister to the rest of the subtribe. Aiphanes is resolved as sister to Bactris and Astrocaryum. Species‐level relationships recovered within Astrocaryum and Bactris disagree to a large extent with previous morphology‐based infrageneric classifications, suggesting that those characters are homoplasious, particularly within Bactris. A Bayesian dating analysis using the relaxed‐clock model indicates that most genera of Bactridinae diverged during a relatively short period around the Eocene–Oligocene boundary, which might explain the difficulties in resolving the phylogenetic backbone of the group. The mostly Andean genus Aiphanes shows an initial radiation of early lineages in the Oligocene (around 25 Ma ago) corresponding to an early uplift phase of the cordillera. These taxa are nowadays restricted to the mountain forests of Colombia and Ecuador. The main diversification of Andean Aiphanes began in the Miocene (around 11 Ma ago). This study provides the first substantial insight into Bactridinae phylogeny and sets the stage for more comprehensively sampled species‐level studies analysing drivers of diversity of Neotropical palms, speciation patterns, character evolution, or biogeography.

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A dated phylogeny of the palm tribe Chamaedoreeae supports Eocene dispersal between Africa, North and South America

Cuenca¹,

Lange²,

Borchsenius³

2008

Molecular Phylogenetics and Evolution

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Molecular phylogeny of Plagiothecium and similar hypnalean mosses, with a revised sectional classification of Plagiothecium

2017

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We investigated the systematic relationships within the pleurocarpous moss genus Plagiothecium, based on cladistic analyses of sequence data from one nuclear (ITS) and two plastid (trnK-psbA (matK) and rpl16 intron) DNA regions for 110 specimens of Plagiothecium and similar hypnalean mosses. Plastid and nuclear trees were mostly similar, but differed in the placement of several species of Plagiothecium, and in the relationships among other genera. The phylogenetic hypotheses based on plastid markers were well resolved; in contrast, nuclear data were insufficient to resolve some of the lowest-level relationships within the genus. In the main Plagiothecium is natural, includes more taxa than are often recognized, and is most closely related to Isopterygiopsis and Herzogiella. Nine sections are recognized within Plagiothecium, four new: Section Pseudo-Neckera to accommodate P. neckeroideum and its allies, Section Ortholimnobium for P. handelii and P. paleaceum, Section Struckia for P. argentatum and P. enerve, and Section Rectithecium for P. piliferum. The geographical distribution of the sections suggests that Plagiothecium originated in Asia. The derived, mainly autoicous sections Plagiothecium and Leptophyllum may have spread to the Southern Hemisphere through long distance dispersal. Three new species in section Leptophyllum (P. funale, P. pacificum and P. rhizolucidum) and two new taxa in section Pseudo-Neckera (P. decoratum and P. neckeroideum fo. exile) are described. A limited phylogenetic hypothesis for the superficially similar hypnalean genus Taxiphyllum, which was used as outgroup, is included. A related genus (Longiella) is described, with a single species (L. plagiothecioides). The aquarium species T. barbieri is transferred to Ectropothecium.

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