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Inferring Trees from Trees Consensus and Supertree Methods

Department of Zoology, The Natural History Museum mw@bmnh.org. Inferring Trees from Trees Consensus and Supertree Methods. Mark Wilkinson. CONSENSUS “general or widespread agreement”. Consensus tree – a tree depicting agreement among a set of trees - a representation of a set of trees

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Inferring Trees from Trees Consensus and Supertree Methods

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  1. Department of Zoology, The Natural History Museum mw@bmnh.org Inferring Trees from TreesConsensus and Supertree Methods Mark Wilkinson

  2. CONSENSUS“general or widespread agreement” • Consensus tree – a tree depicting agreement among a set of trees - a representation of a set of trees - a phylogenetic inference from a set of trees • Consensus method – a technique for producing consensus trees (of a particular type) • Consensus index – a measure of the agreement among a set of trees (based on their consensus tree)

  3. Uses of Consensus Trees • Consensus trees are used to represent (or make inferences from) multiple trees Agreement (conservative) Central tendency (liberal) • There are a number of different contexts in which this may be of interest (sets of trees can be obtained in a variety of ways) • The ultimate aims may be quite different • Different methods may be more or less appropriate given the aim/context

  4. Mathematician’s Perspective Subsequently there has been an amazing proliferation of consensus methods and consensus indices): a proliferation stimulated by confusions, disagreements, and uncertainties concerning what consensus methods depict and what consensus indices measure. Thus, for example, consensus indices for trees are understood to measure agreement, balance, information, resolution, shape, similarity, and symmetry. One has the impression that taxonomists do not know (or cannot agree on) what consensus objects should depict or how it should be depicted; they do not know (or cannot agree on) what consensus indices should measure or how it should be quantified. Consequently, taxonomists may not appreciate (or do not articulate) the relationships that might or should exist between consensus method and consensus index. Day and McMorris 1985

  5. Strict (Component) CM Uniquely defined in terms of two properties Pareto - if a component is present in all the input trees it is in the consensus Strict - if a component is in the consensus it is present in all the input trees Can also be defined in terms of an algorithm an objective function

  6. Strict CM(s) • Require complete agreement across all the input trees and show relationships that would be true if any input tree were true • With MPTs they show only those relationships that are unambiguously supported by the parsimonious interpretation of the data • The commonest method focuses on components (clusters, groups, splits, clades or monophyletic groups) • This method produces a consensus tree that includes all (Pareto) and only (strict) the common clades Other relationships (those in which the input trees disagree) are shown as unresolved polytomies • Component version widely implemented

  7. Strict CM(s) TWO INPUT TREES A B C D E F G B E F G A C D B D F G A C E STRICT (COMPONENT) CONSENSUS TREE

  8. Interpreting Polytomies • Polytomies in trees have alternative interpretations. • The hardinterpretation ‘multiple speciation’ • The soft interpretation ‘uncertain resolution’ • The soft interpretation is appropriate for strict component consensus trees • The consensus permits all resolutions of the polytomy (i.e. it does not conflict with any resolution)

  9. Semi-strict CM(s) • Semi-strict methods require assertion of a relationship by one or more trees and non-contradiction by any tree • The commonest method focuses on components/clades • Produces a tree including all components that are present and uncontradicted in the input trees - all that could be true if any input tree were true • Generally, similar to the strict but may be more resolved when the input trees include polytomies • It is based on the soft interpretation of polytomies • Other relationships are shown as unresolved polytomies • Component version implemented in e.g. PAUP

  10. Semi-strict (component) CM TWO INPUT TREES

  11. Properties of Semi-strict CM(s) • Tend to produce more resolved consensus trees • Reasonable when combining trees based on different data set • With trees based on a single data set extra resolution is of relationships that are not true of all the optimal trees: the consensus includes relationships that are not supported by all best interpretations of the data It may include relationships that cannot be simultaneously supported by any parsimonious (or other) interpretation of the data These relationships might reasonably be considered less well supported (if supported at all)

  12. Semi-strict (component) CM TWO INPUT TREES SEMI-STRICT (component) CONSENSUS TREE

  13. Equally Optimal Trees • Many phylogenetic analyses yield multiple equally optimal trees • Multiple trees are due to either: Alternative equally optimal interpretations of conflicting data Missing data Or both • We can further select among these trees with additional (secondary) criteria, but • A consensus tree may be needed to represent or draw conclusions about the set of MTPs • Typically phylogeneticists are interested in relationships common to all the optimal trees (they want to know that a relationship in the consensus is in all the trees - STRICT)

  14. Loss of Resolution • Generally, as the number of optimal trees increases the resolution of ‘strict consensus trees’ decreases. • In the extreme, the ‘strict consensus tree’ may be completely unresolved/uninformative. • This extreme is sometimes met in practice (e.g. fossils). • The ‘consensus tree’ can also be poorly resolved when there are few optimal trees, and.furthermore. • The optimal trees need not differ greatly, thus... • Lack of resolution in a ‘strict consensus tree’ is not always a good guide to the level of agreement among the optimal trees.

  15. Optimal trees need not differ greatly for ‘the consensus tree’ to be unresolved

  16. Adams-2 Consensus Adams (1972) method was defined by a recursive algorithm, which, beginning at the root, identifies common sub-clusters using intersection rules (product partitions) The basal splits in these trees yield the four clusters ABC, EFD, AC & BEFD. Their intersections yield AC, B & EFD and these produce the three branches at the base of the consensus tree. The procedure is repeated for the subtrees induced by E, F and D, which in this case are identical.

  17. Adams Consensus and Nesting • Adams (1972) described the first consensus methods, only one of his methods is used • Adams (1986) characterised his method in terms ofnestings • A group X (e.g. AB) nests within another Y (e.g. A-D) if the last common ancestor of Y is an ancestor of the last common ancestor of X • The Adams consensus tree includes all those nestings that are in all the input trees (Pareto) and for all clusters displayed by the Adams tree there is a corresponding nesting in each input tree (strict). • They show only those nestings that are unambiguously supported by the parsimonious interpretation of the data • Implemented in e.g. PAUP

  18. Adams Consensus and Nesting (1) taxa A & C are more closely related to each other than either is to taxa D, E, or F; (2) taxa E & F are more closely related to each other than either is to taxa A, C, or D; (3) taxon D is more closely related to E & F than it is to either A or C. Swofford (1991) But - Not quite right!

  19. Adams Consensus (1) taxa A & C are more closely related to each other than either is to taxa D, E, or F; In each tree A & C are more closely related to each other than they are to D-F and/or B (AC)D-F and/or (AC)B (2) taxa E & F are more closely related to each other than either is to taxa A, C, or D; (EF)D (3) taxon D is more closely related to E & F than it is to either A or C. (D-F)AC and/or (D-F)B

  20. Adams polytomies are cladistically ambiguous What can be inferred from the consensus? (A,B)CD - No (AB)C - No (AB)D - No (AB)C and/or (AB)D INPUT TREES

  21. Note on the meaning of cladistic relationship • Cladistic relationships are based on recency of common ancestry (& dependent on rooted trees). • Two taxa are more closely related to each other than either is to a third iff they share a more recent common ancestor - e.g. (AB)CDE. • Nestings are also based on common ancestry but nestings are ambiguous with respect to cladistic relationships - e.g. {AB}CD = (AB)C and/or (AB)D

  22. Properties of Adams Consensus Trees • Adams consensus trees are more topologically sensitive to shared structure in input trees than is the strict component consensus, but... • Care must be taken in the interpretation of their ‘elastic’ polytomies • Adams consensus trees can include groups that don’t occur in any input tree (Rholf Groups) • It exists only for rooted trees

  23. Greatest Agreement Subtrees TWO INPUT TREES B D F G A G B C D E F A C E A G D E C B F B D F A C E Strict component consensus completely unresolved GAS/LCP TREE Taxon G is excluded

  24. Strict component consensus A G D E C B F A D F C E B D F C E A D F B E Strict Reduced CM TWO INPUT TREES B D F G A G B C D E F A C E B D F A C E STRICT REDUCED CONSENSUS TREE Agreement Subtrees Taxon G is excluded

  25. Rhynchosaurs

  26. Fossil & Recent Arthropods

  27. Fossil & Recent Arthropods

  28. Majority-rule CM(s) • Majority-rule consensus methods require agreement across a majority of the input trees • The commonest method focuses on components/clades • This method produces a consensus tree that includes all and only those clades found in a majority (>50%) of the input trees • Majority components which are necessarily mutually compatible • Other relationships are shown as unresolved polytomies • Of particular use in bootstrapping, jackknifing, quartet puzzling, Bayesian inference (with e.g. average branch lengths). • Component version widely implemented

  29. Majority-rule (component) CM THREE INPUT TREES A B C D E F G B E F G B E D G A C D A C F A B C E D F G 66 100 Numbers indicate frequency of clades in the input trees 66 66 66 MAJORITY-RULE (COMPONENT) CONSENSUS

  30. Properties of Majority-rule • Tend to produce more resolved consensus trees • Extra resolution is of relationships that are not true of all the optimal trees • In the context of equally optimal trees, this means the consensus includes relationships that are not supported by all the best interpretations of the data • These relationships might reasonably be considered less well supported (if supported at all) • Related to the Median consensus (objective function minimises the sum of the symmetric differences between the consensus and input trees)

  31. Adding minority components • Further resolution can sometimes be achieved by adding relationships that occur in a minority of trees. • These must be compatible with the majority relationships • Two approaches Greedy (PAUP) Frequency-difference (TNT)

  32. Majority-rule

  33. Other Consensus methods • A variety of other consensus methods have been devised but few implemented • These include: Other intersection rules based on cluster height Nelson, Asymmetric Median and other clique consensus methods Other matrix respresentation methods, e.g. MRP Average consensus

  34. A Consensus Classification • Consensus trees vary with respect to: The kind of agreement (components, triplets, nestings, subtrees) The level of agreement (strict, semi-strict, majority-rule, largest clique) Adams Reduced LCP / GAS Full Splits Nestings Splits Subtrees Strict Yes Yes Yes Yes Semi-strict Yes ? Yes ? Majority-rule Yes ? Yes ? Nelson (clique) Yes ? Yes ?

  35. Consensus methods • Use strict methods to identify those relationships unambiguously supported by parsimonious interpretation of the data • Use more liberal (semi-strict, majority-rule) consensus methods for taxonomic congruence • Use majority-rule methods in bootstrapping etc. • Use Adams consensus when strict component consensus is poorly resolved - if Adams is better resolved use strict reduced consensus • Use reduced methods where consensus trees are poorly resolved • Avoid over-interpreting results from methods which have ambiguous interpretations

  36. Input Trees Consensus Trees More or less Conservative More or less Liberal

  37. Input Trees SuperTrees More or less Conservative More or less Liberal

  38. Biologists want (Big) Trees • “Nothing in Biology makes sense except in the light of evolution” Dobzhansky, 1973 • The Tree of Life: Holy Grail of Systematics • Bigger Trees: more powerful comparative analyses • Adaptation • Biogeography • Speciation and diversification • Conservation

  39. When Input Trees Conflict • Semi-strict • Gene Tree Parsimony • MinCut (modified Aho) • Quartet puzzling • Matrix representations • Splits (standard MRP, MRC, MRF) • Sister groups (Purvis MRP) • Triplets • Quartets • Distances (MRD) • Analysed with • Parsimony (MRP) - ,  • Clique (MRC) • MinFlip (MRF) • Least squares

  40. MRP Tree 2 Tree 1 Component Purvis Triplet Fecampiida 111 111 111 111 1??11??111 Neodermata ??? 111 ??? 111 ?????????? Tricladida 111 100 111 10? ?1???11111 Lecithoepitheliata 110 000 110 0?? ??111110?? Polycladida 000 ??? 00? ??? 0000?0??0? Kalytporhyncha 100 110 1?? 110 111?0?0??0 MRP-outgroup 000 000 000 000 0000000000

  41. MRP B A Components unordered - A,B,C irreversible - C Triplets - A Quartets - A & C C

  42. MRP – an unusual consensus

  43. MRP, total evidence and taxonomic congruence

  44. Majority-rule Goloboff and Pol (2002), Goloboff (2006) Majority rule supertrees desirable in principle Fundamental problem in generalising frequency of occurrence of groups MRP is a (poor) surrogate

  45. Majority-rule • Majority-rule consensus is also a median tree for the symmetric difference • Alternative basis for generalising beyond consensus • How to compute symmetric difference for trees with different leaf sets? • Convert into trees with identical leaf sets • Prune leaves from supertree • Graft leaves onto supertree

  46. ML Supertrees

  47. ‘Taxonomic Congruence’

  48. ‘Taxonomic Congruence’

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