Assessment of the Accuracy of Matrix Representation with Parsimony Analysis Supertree Construction

Bininda‐Emonds, Olaf R. P.; Sanderson, Michael J.

doi:10.1080/10635150120358

Cited by 118 publications

(140 citation statements)

References 38 publications

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“…Thus, despite the sparseness of our alignment matrix (94% of the cells were missing data) the topological arrangements closely approximated expected relationships according to APG II. The importance of including in a supermatrix one gene that is present for all taxa and readily aligns across the full matrix, e.g., rbcL in our analysis, has been shown in other studies using supermatrices for building phylogenies (8,9).…”

Section: Discussionmentioning

confidence: 87%

“…In this respect a supermatrix design (8,9) is ideal for using a mixture of coding genes and intergenic spacers for phylogenetic reconstruction across the broadest evolutionary distances, as in the construction of community phylogenies (10). We define a supermatrix as a phylogenetic matrix that may contain a high incidence of missing data and the data content for any one taxon is stochastic (11) (Fig.…”

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confidence: 99%

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Plant DNA barcodes and a community phylogeny of a tropical forest dynamics plot in Panama

Kress

Erickson

Jones

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

628

695

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The assembly of DNA barcode libraries is particularly relevant within species-rich natural communities for which accurate species identifications will enable detailed ecological forensic studies. In addition, well-resolved molecular phylogenies derived from these DNA barcode sequences have the potential to improve investigations of the mechanisms underlying community assembly and functional trait evolution. To date, no studies have effectively applied DNA barcodes sensu strictu in this manner. In this report, we demonstrate that a three-locus DNA barcode when applied to 296 species of woody trees, shrubs, and palms found within the 50-ha Forest Dynamics Plot on Barro Colorado Island (BCI), Panama, resulted in >98% correct identifications. These DNA barcode sequences are also used to reconstruct a robust community phylogeny employing a supermatrix method for 281 of the 296 plant species in the plot. The three-locus barcode data were sufficient to reliably reconstruct evolutionary relationships among the plant taxa in the plot that are congruent with the broadly accepted phylogeny of flowering plants (APG II). Earlier work on the phylogenetic structure of the BCI forest dynamics plot employing less resolved phylogenies reveals significant differences in evolutionary and ecological inferences compared with our data and suggests that unresolved community phylogenies may have increased type I and type II errors. These results illustrate how highly resolved phylogenies based on DNA barcode sequence data will enhance research focused on the interface between community ecology and evolution.T he most difficult challenge for DNA barcoding in plants is discriminating among taxa of highly speciose genera where rates of species identification by using a variety of putative barcodes rarely exceed 70% (1). In some cases of complex recently evolved species groups DNA barcoding may simply be inappropriate as an identification tool (2). This difficulty is especially acute in cases where certain life history traits have affected the rates of molecular evolution in a lineage, which in turn may affect rates of species assignment by DNA barcodes [e.g., generation times (3) and age-of-crown group diversification (4)].In the absence of a universal barcode region capable of discriminating among all species in all groups of plants, it is clear that DNA barcodes will be most effectively applied in the identification of a circumscribed set of species that occur together in a floristic region or ecological community, rather than in distinguishing among an exhaustive sample of taxonomically closely related species. In these cases only a limited number of closely related species occur in the same region, so identification to genus is all that is required.It is now generally agreed that a plant barcode will combine more than one locus (5-7) and will include a phylogenetically conservative coding locus (rbcL) with one or more rapidly evolving regions (part of the matK gene and the intergenic spacer trnH-psbA). Although more laborious than a si...

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Section: Discussionmentioning

confidence: 87%

mentioning

confidence: 99%

Plant DNA barcodes and a community phylogeny of a tropical forest dynamics plot in Panama

Kress

Erickson

Jones

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

628

695

View full text Add to dashboard Cite

show abstract

“…For instance, the popular matrix representation with parsimony (MRP) method [3,35] has relatively low accuracy when the input trees overlap moderately and [12] recommends adding to the set of input trees a tree with leaves spanning most input trees, that they call a seed tree. Any supertree that is a solution of SMAST or SMCT most likely contains leaves from most, if not all, input trees (see Theorem 3) and, moreover, fully agrees with all of these trees by definition.…”

Section: Introductionmentioning

confidence: 99%

Maximum Agreement and Compatible Supertrees

Berry

Nicolas

2004

Lecture Notes in Computer Science

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Given a set of leaf-labelled trees with identical leaf sets, the MAST problem, respectively MCT problem, consists of finding a largest subset of leaves such that all input trees restricted to these leaves are isomorphic, respectively compatible. In this paper, we propose extensions of these problems to the context of supertree inference, where input trees have non-identical leaf sets. This situation is of particular interest in phylogenetics. The resulting problems are called SMAST and SMCT.A sufficient condition is given that identifies cases where these problems can be solved by resorting to MAST and MCT as subproblems. This condition is met, for instance, when only two input trees are considered. Then we give algorithms for SMAST and SMCT that benefit from the link with the subtree problems. These algorithms run in time linear to the time needed to solve MAST, respectively MCT, on an instance of the same or smaller size.It is shown that arbitrary instances of SMAST and SMCT can be turned in polynomial time into instances composed of trees with a bounded number of leaves.SMAST is shown to be W[2]-hard when the considered parameter is the number of input leaves that have to be removed to obtain the agreement of the input trees. A simlar result holds for SMCT. Moreover, the corresponding optimization problems, that is the complements of SMAST and SMCT, can not be approximated in polynomial time within a constant factor, unless P = NP. These results also hold when the input trees have a bounded number of leaves.The presented results apply to both collections of rooted and unrooted trees.

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“…Thus weighting schemes can be used that reflect measures of support for components or triplets, such as bootstrap proportions (Felsenstein, 1985;Wilkinson, 1996) or decay indices (Bremer, 1988;Donoghue et al, 1992;Wilkinson et al, 2000). Ronquist (1996) argued the virtues of differential weighting in the context of MRP and simulations suggest that weighting in this context can improve accuracy (Bininda-Emonds and Sanderson, 2001).…”

Section: Plenarymentioning

confidence: 99%

“…The ability of any method to construct accurate supertrees under a range of readily modeled analytical conditions can be assessed by simulation (e.g. Bininda-Emonds and Sanderson, 2001;Chen et al, 2003;Lapointe and Levasseur, this volume;Ross and Rodrigo, this voume). However, the ability of methods to produce accurate trees depends very much on properties of the data, and insights from simulations notwithstanding, for the most part we do not know how accurate real supertrees are.…”

Section: Accuracymentioning

confidence: 99%

Some Desiderata for Liberal Supertrees

Wilkinson¹,

Thorley²,

Pisani³

et al. 2004

Computational Biology

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Abstract:Although a variety of supertree methods has been proposed, our understanding of these methods is limited. In turn, this limits the potential for biologists who seek to construct supertrees to make informed choices among the available methods. In this chapter we distinguish between supertree methods that offer a conservative synthesis of the relationships that are agreed upon or uncontradicted by all the input trees and liberal supertree methods which have the potential to resolve conflict. We list a series of potential desiderata (i.e. desirable properties) of liberal supertree methods, discuss their relevance to biologists and highlight where it is known that particular methods do or do not satisfy them. For biologists, the primary aim of liberal supertree construction is to produce accurate phylogenies and most of our desiderata relate to this prime objective. Secondary desiderata pertain to the practicality of supertree methods, particularly their speed.

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Assessment of the Accuracy of Matrix Representation with Parsimony Analysis Supertree Construction

Cited by 118 publications

References 38 publications

Plant DNA barcodes and a community phylogeny of a tropical forest dynamics plot in Panama

Plant DNA barcodes and a community phylogeny of a tropical forest dynamics plot in Panama

Maximum Agreement and Compatible Supertrees

Some Desiderata for Liberal Supertrees

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