Phylogenetics
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In biology, phylogenetics /ˌfaɪloʊdʒəˈnɛtɪks, -lə-/[1][2] (from Greek φυλή/φῦλον (phylé/phylon) "tribe, clan, race", and γενετικός (genetikós) "origin, source, birth")[3] is a part of systematics that addresses the inference of the evolutionary history and relationships among or within groups of organisms (e.g. species, or more inclusive taxa). These relationships are hypothesized by phylogenetic inference methods that evaluate observed heritable traits, such as DNA sequences, protein amino acid sequences, or morphology, often under a specified model of evolution of these traits. The result of such an analysis is a phylogeny (also known as a phylogenetic tree)—a diagrammatic hypothesis of relationships that reflects the evolutionary history of a group of organisms.[4] The tips of a phylogenetic tree can be living taxa or fossils, and represent the 'end', or the present, in an evolutionary lineage. A phylogenetic diagram can be rooted or unrooted. A rooted tree diagram indicates the hypothetical common ancestor, or ancestral lineage, of the tree. An unrooted tree diagram (a network) makes no assumption about the ancestral line, and does not show the origin or "root" of the taxa in question or the direction of inferred evolutionary transformations.[5] In addition to their proper use for inferring phylogenetic patterns among taxa, phylogenetic analyses are often employed to represent relationships among gene copies or individual organisms. Such uses have become central to understanding biodiversity, evolution, ecology, and genomes. In February 2021, scientists reported, for the first time, the sequencing of DNA from animal remains, a mammoth in this instance, over a million years old, the oldest DNA sequenced to date.[6][7]
Taxonomy is the identification, naming and classification of organisms. Classifications are now usually based on phylogenetic data, and many systematists contend that only monophyletic taxa should be recognized as named groups. The degree to which classification depends on inferred evolutionary history differs depending on the school of taxonomy: phenetics ignores phylogenetic speculation altogether, trying to represent the similarity between organisms instead; cladistics (phylogenetic systematics) tries to reflect phylogeny in its classifications by only recognizing groups based on shared, derived characters (synapomorphies); evolutionary taxonomy tries to take into account both the branching pattern and "degree of difference" to find a compromise between them.
Inference of a phylogenetic tree[]
Usual methods of phylogenetic inference involve computational approaches implementing the optimality criteria and methods of parsimony, maximum likelihood (ML), and MCMC-based Bayesian inference. All these depend upon an implicit or explicit mathematical model describing the evolution of characters observed.
Phenetics, popular in the mid-20th century but now largely obsolete, used distance matrix-based methods to construct trees based on overall similarity in morphology or similar observable traits (i.e. in the phenotype or the overall similarity of DNA, not the DNA sequence), which was often assumed to approximate phylogenetic relationships.
Prior to 1950, phylogenetic inferences were generally presented as narrative scenarios. Such methods are often ambiguous and lack explicit criteria for evaluating alternative hypotheses.[8][9][10]
History[]
The term "phylogeny" derives from the German Phylogenie, introduced by Haeckel in 1866,[11] and the Darwinian approach to classification became known as the "phyletic" approach.[12]
Ernst Haeckel's recapitulation theory[]
During the late 19th century, Ernst Haeckel's recapitulation theory, or "biogenetic fundamental law", was widely accepted. It was often expressed as "ontogeny recapitulates phylogeny", i.e. the development of a single organism during its lifetime, from germ to adult, successively mirrors the adult stages of successive ancestors of the species to which it belongs. But this theory has long been rejected.[13][14] Instead, ontogeny evolves – the phylogenetic history of a species cannot be read directly from its ontogeny, as Haeckel thought would be possible, but characters from ontogeny can be (and have been) used as data for phylogenetic analyses; the more closely related two species are, the more apomorphies their embryos share.
Timeline of key points[]
- 14th century, lex parsimoniae (parsimony principle), William of Ockam, English philosopher, theologian, and Franciscan friar, but the idea actually goes back to Aristotle, precursor concept
- 1763, Bayesian probability, Rev. Thomas Bayes,[15] precursor concept
- 18th century, Pierre Simon (Marquis de Laplace), perhaps first to use ML (maximum likelihood), precursor concept
- 1809, evolutionary theory, Philosophie Zoologique, Jean-Baptiste de Lamarck, precursor concept, foreshadowed in the 17th century and 18th century by Voltaire, Descartes, and Leibniz, with Leibniz even proposing evolutionary changes to account for observed gaps suggesting that many species had become extinct, others transformed, and different species that share common traits may have at one time been a single race,[16] also foreshadowed by some early Greek philosophers such as Anaximander in the 6th century BC and the atomists of the 5th century BC, who proposed rudimentary theories of evolution[17]
- 1837, Darwin's notebooks show an evolutionary tree[18]
- 1843, distinction between homology and analogy (the latter now referred to as homoplasy), Richard Owen, precursor concept
- 1858, Paleontologist Heinrich Georg Bronn (1800–1862) published a hypothetical tree to illustrating the paleontological "arrival" of new, similar species following the extinction of an older species. Bronn did not propose a mechanism responsible for such phenomena, precursor concept.[19]
- 1858, elaboration of evolutionary theory, Darwin and Wallace,[20] also in Origin of Species by Darwin the following year, precursor concept
- 1866, Ernst Haeckel, first publishes his phylogeny-based evolutionary tree, precursor concept
- 1893, Dollo's Law of Character State Irreversibility,[21] precursor concept
- 1912, ML recommended, analyzed, and popularized by Ronald Fisher, precursor concept
- 1921, Tillyard uses term "phylogenetic" and distinguishes between archaic and specialized characters in his classification system[22]
- 1940, term "clade" coined by Lucien Cuénot
- 1949, Jackknife resampling, Maurice Quenouille (foreshadowed in '46 by Mahalanobis and extended in '58 by Tukey), precursor concept
- 1950, Willi Hennig's classic formalization[23]
- 1952, William Wagner's groundplan divergence method[24]
- 1953, "cladogenesis" coined[25]
- 1960, "cladistic" coined by Cain and Harrison[26]
- 1963, first attempt to use ML (maximum likelihood) for phylogenetics, Edwards and Cavalli-Sforza[27]
- 1965
- 1966
- English translation of Hennig[30]
- "cladistics" and "cladogram" coined (Webster's, loc. cit.)
- 1969
- 1970, Wagner parsimony generalized by Farris[34]
- 1971
- first successful application of ML to phylogenetics (for protein sequences), Neyman[35]
- Fitch parsimony, Fitch[36]
- NNI (nearest neighbour interchange), first branch-swapping search strategy, developed independently by Robinson[37] and Moore et al.
- ME (minimum evolution), Kidd and Sgaramella-Zonta[38] (it is unclear if this is the pairwise distance method or related to ML as Edwards and Cavalli-Sforza call ML "minimum evolution")
- 1972, Adams consensus, Adams[39]
- 1976, prefix system for ranks, Farris[40]
- 1977, Dollo parsimony, Farris[41]
- 1979
- 1980, PHYLIP, first software package for phylogenetic analysis, Felsenstein
- 1981
- 1982
- PHYSIS, Mikevich and Farris
- branch and bound, Hendy and Penny[48]
- 1985
- 1986, MacClade, Maddison and Maddison
- 1987, neighbor-joining method Saitou and Nei[52]
- 1988, Hennig86 (version 1.5), Farris
- Bremer support (decay index), Bremer[53]
- 1989
- 1990
- 1991
- 1993, implied weighting Goloboff[60]
- 1994, reduced consensus: RCC (reduced cladistic consensus) for rooted trees, Wilkinson[61]
- 1995, reduced consensus RPC (reduced partition consensus) for unrooted trees, Wilkinson[62]
- 1996, first working methods for BI (Bayesian Inference)independently developed by Li,[63] Mau,[64] and Rannala and Yang[65] and all using MCMC (Markov chain-Monte Carlo)
- 1998, TNT (Tree Analysis Using New Technology), Goloboff, Farris, and Nixon
- 1999, Winclada, Nixon
- 2003, symmetrical resampling, Goloboff[66]
- 2004,2005, symmilarity metric (using an approximation to Kolmogorov complexity) or NCD (normalized compression distance), Li et al.,[67] Cilibrasi and Vitanyi.[68]
Outside biology[]
Phylogenetic tools and representations (trees and networks) can also be applied to studying the evolution of languages, in the field of quantitative comparative linguistics.[69]
See also[]
- Angiosperm Phylogeny Group
- Bauplan
- Bioinformatics
- Biomathematics
- Coalescent theory
- EDGE of Existence programme
- Evolutionary taxonomy
- Joe Felsenstein
- Language family
- Maximum parsimony
- Microbial phylogenetics
- Molecular phylogeny
- Noogenesis
- Ontogeny
- PhyloCode
- Phylodynamics
- Phylogenesis
- Phylogenetic comparative methods
- Phylogenetic network
- Phylogenetic nomenclature
- Phylogenetic tree viewers
- Phylogenetics software
- Phylogenomics
- Phylogeny (psychoanalysis)
- Phylogeography
- Systematics
References[]
- ^ "phylogenetic". Dictionary.com Unabridged. Random House.
- ^ "phylogenetic". Merriam-Webster Dictionary.
- ^ Liddell, Henry George; Scott, Robert; Jones, Henry Stuart (1968). A Greek-English lexicon (9 ed.). Oxford: Clarendon Press. p. 1961.
- ^ "phylogeny". Biology online. Retrieved 15 February 2013.
- ^ "Phylogenetic Trees". www.cs.tau.ac.il. Retrieved 27 April 2019.
- ^ Hunt, Katie (17 February 2021). "World's oldest DNA sequenced from a mammoth that lived more than a million years ago". CNN News. Retrieved 17 February 2021.
- ^ Callaway, Ewen (17 February 2021). "Million-year-old mammoth genomes shatter record for oldest ancient DNA - Permafrost-preserved teeth, up to 1.6 million years old, identify a new kind of mammoth in Siberia". Nature. doi:10.1038/d41586-021-00436-x. Retrieved 17 February 2021.
- ^ Richard C. Brusca & Gary J. Brusca (2003). Invertebrates (2nd ed.). Sunderland, Massachusetts: Sinauer Associates. ISBN 978-0-87893-097-5.
- ^ Bock, W. J. (2004). Explanations in systematics. Pp. 49–56. In Williams, D. M. and Forey, P. L. (eds) Milestones in Systematics. London: Systematics Association Special Volume Series 67. CRC Press, Boca Raton, Florida.
- ^ Auyang, Sunny Y. (1998). Narratives and Theories in Natural History. In: Foundations of complex-system theories: in economics, evolutionary biology, and statistical physics. Cambridge, U.K.; New York: Cambridge University Press.[page needed]
- ^ Harper, Douglas (2010). "Phylogeny". Online Etymology Dictionary.
- ^ Stuessy 2009.
- ^ Blechschmidt, Erich (1977) The Beginnings of Human Life. Springer-Verlag Inc., p. 32: "The so-called basic law of biogenetics is wrong. No buts or ifs can mitigate this fact. It is not even a tiny bit correct or correct in a different form, making it valid in a certain percentage. It is totally wrong."
- ^ Ehrlich, Paul; Richard Holm; Dennis Parnell (1963) The Process of Evolution. New York: McGraw–Hill, p. 66: "Its shortcomings have been almost universally pointed out by modern authors, but the idea still has a prominent place in biological mythology. The resemblance of early vertebrate embryos is readily explained without resort to mysterious forces compelling each individual to reclimb its phylogenetic tree."
- ^ Bayes, Mr; Price, Mr (1763). "An Essay towards Solving a Problem in the Doctrine of Chances. By the Late Rev. Mr. Bayes, F. R. S. Communicated by Mr. Price, in a Letter to John Canton, A. M. F. R. S". Philosophical Transactions of the Royal Society of London. 53: 370–418. doi:10.1098/rstl.1763.0053.
- ^ Strickberger, Monroe. 1996. Evolution, 2nd. ed. Jones & Bartlett.[page needed]
- ^ The Theory of Evolution, Teaching Company course, Lecture 1
- ^ Darwin's Tree of Life Archived 13 March 2014 at the Wayback Machine
- ^ Archibald, J. David (2008). "Edward Hitchcock's Pre-Darwinian (1840) 'Tree of Life'". Journal of the History of Biology. 42 (3): 561–92. CiteSeerX 10.1.1.688.7842. doi:10.1007/s10739-008-9163-y. PMID 20027787. S2CID 16634677.
- ^ Darwin, Charles; Wallace, Alfred (1858). "On the Tendency of Species to form Varieties; and on the Perpetuation of Varieties and Species by Natural Means of Selection". Journal of the Proceedings of the Linnean Society of London. Zoology. 3 (9): 45–62. doi:10.1111/j.1096-3642.1858.tb02500.x.
- ^ Dollo, Louis. 1893. Les lois de l'évolution. Bull. Soc. Belge Géol. Paléont. Hydrol. 7: 164–66.
- ^ Tillyard, R. J (2012). "A New Classification of the Order Perlaria". The Canadian Entomologist. 53 (2): 35–43. doi:10.4039/Ent5335-2.
- ^ Hennig, Willi (1950). Grundzüge einer Theorie der Phylogenetischen Systematik [Basic features of a theory of phylogenetic systematics] (in German). Berlin: Deutscher Zentralverlag. OCLC 12126814.[page needed]
- ^ Wagner, Warren Herbert (1952). "The fern genus Diellia: structure, affinities, and taxonomy". University of California Publications in Botany. 26 (1–6): 1–212. OCLC 4228844.
- ^ Webster's 9th New Collegiate Dictionary
- ^ Cain, A. J; Harrison, G. A (2009). "Phyletic Weighting". Proceedings of the Zoological Society of London. 135 (1): 1–31. doi:10.1111/j.1469-7998.1960.tb05828.x.
- ^ "The reconstruction of evolution" in "Abstracts of Papers". Annals of Human Genetics. 27 (1): 103–5. 1963. doi:10.1111/j.1469-1809.1963.tb00786.x.
- ^ Camin, Joseph H; Sokal, Robert R (1965). "A Method for Deducing Branching Sequences in Phylogeny". Evolution. 19 (3): 311–26. doi:10.1111/j.1558-5646.1965.tb01722.x. S2CID 20957422.
- ^ Wilson, Edward O (1965). "A Consistency Test for Phylogenies Based on Contemporaneous Species". Systematic Zoology. 14 (3): 214–20. doi:10.2307/2411550. JSTOR 2411550.
- ^ Hennig. W. (1966). Phylogenetic systematics. Illinois University Press, Urbana.[page needed]
- ^ Farris, James S (1969). "A Successive Approximations Approach to Character Weighting". Systematic Zoology. 18 (4): 374–85. doi:10.2307/2412182. JSTOR 2412182.
- ^ Jump up to: a b Kluge, A. G; Farris, J. S (1969). "Quantitative Phyletics and the Evolution of Anurans". Systematic Biology. 18 (1): 1–32. doi:10.1093/sysbio/18.1.1.
- ^ Quesne, Walter J. Le (1969). "A Method of Selection of Characters in Numerical Taxonomy". Systematic Zoology. 18 (2): 201–205. doi:10.2307/2412604. JSTOR 2412604.
- ^ Farris, J. S (1970). "Methods for Computing Wagner Trees". Systematic Biology. 19: 83–92. doi:10.1093/sysbio/19.1.83.
- ^ Neyman, J. (1971). Molecular studies: A source of novel statistical problems. In: Gupta S. S., Yackel J. (eds), Statistical Decision Theory and Related Topics, pp. 1–27. Academic Press, New York.
- ^ Fitch, W. M (1971). "Toward Defining the Course of Evolution: Minimum Change for a Specific Tree Topology". Systematic Biology. 20 (4): 406–16. doi:10.1093/sysbio/20.4.406. JSTOR 2412116.
- ^ Robinson, D.F (1971). "Comparison of labeled trees with valency three". Journal of Combinatorial Theory, Series B. 11 (2): 105–19. doi:10.1016/0095-8956(71)90020-7.
- ^ Kidd, K. K; Sgaramella-Zonta, L. A (1971). "Phylogenetic analysis: Concepts and methods". American Journal of Human Genetics. 23 (3): 235–52. PMC 1706731. PMID 5089842.
- ^ Adams, E. N (1972). "Consensus Techniques and the Comparison of Taxonomic Trees". Systematic Biology. 21 (4): 390–397. doi:10.1093/sysbio/21.4.390.
- ^ Farris, James S (1976). "Phylogenetic Classification of Fossils with Recent Species". Systematic Zoology. 25 (3): 271–282. doi:10.2307/2412495. JSTOR 2412495.
- ^ Farris, J. S (1977). "Phylogenetic Analysis Under Dollo's Law". Systematic Biology. 26: 77–88. doi:10.1093/sysbio/26.1.77.
- ^ Nelson, G (1979). "Cladistic Analysis and Synthesis: Principles and Definitions, with a Historical Note on Adanson's Familles Des Plantes (1763-1764)". Systematic Biology. 28: 1–21. doi:10.1093/sysbio/28.1.1.
- ^ Gordon, A. D (1979). "A Measure of the Agreement between Rankings". Biometrika. 66 (1): 7–15. doi:10.1093/biomet/66.1.7. JSTOR 2335236.
- ^ Efron B. (1979). Bootstrap methods: another look at the jackknife. Ann. Stat. 7: 1–26.
- ^ Margush, T; McMorris, F (1981). "Consensus-trees". Bulletin of Mathematical Biology. 43 (2): 239. doi:10.1016/S0092-8240(81)90019-7.
- ^ Sokal, Robert R; Rohlf, F. James (1981). "Taxonomic Congruence in the Leptopodomorpha Re-Examined". Systematic Zoology. 30 (3): 309. doi:10.2307/2413252. JSTOR 2413252.
- ^ Felsenstein, Joseph (1981). "Evolutionary trees from DNA sequences: A maximum likelihood approach". Journal of Molecular Evolution. 17 (6): 368–76. Bibcode:1981JMolE..17..368F. doi:10.1007/BF01734359. PMID 7288891. S2CID 8024924.
- ^ Hendy, M.D; Penny, David (1982). "Branch and bound algorithms to determine minimal evolutionary trees". Mathematical Biosciences. 59 (2): 277. doi:10.1016/0025-5564(82)90027-X.
- ^ Lipscomb, Diana (1985). "The Eukaryotic Kingdoms". Cladistics. 1 (2): 127–40. doi:10.1111/j.1096-0031.1985.tb00417.x. S2CID 84151309.
- ^ Felsenstein, J (1985). "Confidence limits on phylogenies: an approach using the bootstrap". Evolution. 39 (4): 783–791. doi:10.2307/2408678. JSTOR 2408678. PMID 28561359.
- ^ Lanyon, S. M (1985). "Detecting Internal Inconsistencies in Distance Data". Systematic Biology. 34 (4): 397–403. CiteSeerX 10.1.1.1000.3956. doi:10.1093/sysbio/34.4.397.
- ^ Saitou, N.; Nei, M. (1987). "The neighbor-joining method: A new method for reconstructing phylogenetic trees". Molecular Biology and Evolution. 4 (4): 406–25. doi:10.1093/oxfordjournals.molbev.a040454. PMID 3447015.
- ^ Bremer, Kåre (1988). "The Limits of Amino Acid Sequence Data in Angiosperm Phylogenetic Reconstruction". Evolution. 42 (4): 795–803. doi:10.1111/j.1558-5646.1988.tb02497.x. PMID 28563878. S2CID 13647124.
- ^ Farris, James S (1989). "The Retention Index and the Rescaled Consistency Index". Cladistics. 5 (4): 417–419. doi:10.1111/j.1096-0031.1989.tb00573.x. S2CID 84287895.
- ^ Archie, James W (1989). "Homoplasy Excess Ratios: New Indices for Measuring Levels of Homoplasy in Phylogenetic Systematics and a Critique of the Consistency Index". Systematic Zoology. 38 (3): 253–269. doi:10.2307/2992286. JSTOR 2992286.
- ^ Bremer, Kåre (1990). "Combinable Component Consensus". Cladistics. 6 (4): 369–372. doi:10.1111/j.1096-0031.1990.tb00551.x. S2CID 84151348.
- ^ D. L. Swofford and G. J. Olsen. 1990. Phylogeny reconstruction. In D. M. Hillis and G. Moritz (eds.), Molecular Systematics, pages 411–501. Sinauer Associates, Sunderland, Mass.
- ^ Goloboff, Pablo A (1991). "Homoplasy and the Choice Among Cladograms". Cladistics. 7 (3): 215–232. doi:10.1111/j.1096-0031.1991.tb00035.x. S2CID 85418697.
- ^ Goloboff, Pablo A (1991). "Random Data, Homoplasy and Information". Cladistics. 7 (4): 395–406. doi:10.1111/j.1096-0031.1991.tb00046.x. S2CID 85132346.
- ^ Goloboff, Pablo A (1993). "Estimating Character Weights During Tree Search". Cladistics. 9: 83–91. doi:10.1111/j.1096-0031.1993.tb00209.x. S2CID 84231334.
- ^ Wilkinson, M (1994). "Common Cladistic Information and its Consensus Representation: Reduced Adams and Reduced Cladistic Consensus Trees and Profiles". Systematic Biology. 43 (3): 343–368. doi:10.1093/sysbio/43.3.343.
- ^ Wilkinson, Mark (1995). "More on Reduced Consensus Methods". Systematic Biology. 44 (3): 435–439. doi:10.2307/2413604. JSTOR 2413604.
- ^ Li, Shuying; Pearl, Dennis K; Doss, Hani (2000). "Phylogenetic Tree Construction Using Markov Chain Monte Carlo". Journal of the American Statistical Association. 95 (450): 493. CiteSeerX 10.1.1.40.4461. doi:10.1080/01621459.2000.10474227. JSTOR 2669394. S2CID 122459537.
- ^ Mau, Bob; Newton, Michael A; Larget, Bret (1999). "Bayesian Phylogenetic Inference via Markov Chain Monte Carlo Methods". Biometrics. 55 (1): 1–12. CiteSeerX 10.1.1.139.498. doi:10.1111/j.0006-341X.1999.00001.x. JSTOR 2533889. PMID 11318142.
- ^ Rannala, Bruce; Yang, Ziheng (1996). "Probability distribution of molecular evolutionary trees: A new method of phylogenetic inference". Journal of Molecular Evolution. 43 (3): 304–11. Bibcode:1996JMolE..43..304R. doi:10.1007/BF02338839. PMID 8703097. S2CID 8269826.
- ^ Goloboff, P (2003). "Improvements to resampling measures of group support". Cladistics. 19 (4): 324–32. doi:10.1111/j.1096-0031.2003.tb00376.x. S2CID 55516104.
- ^ M. Li, X. Chen, X. Li, B. Ma, P.M.B. Vitanyi, The similarity metric, IEEE Trans. Inform. Th., 50:12(2004), 3250--3264
- ^ R. Cilibrasi, P.M.B. Vitanyi, Clustering by compression, IEEE Trans. Information Theory, 51:4(2005), 1523- 1545
- ^ Heggarty, Paul (2006). "Interdisciplinary Indiscipline? Can Phylogenetic Methods Meaningfully Be Applied to Language Data — and to Dating Language?" (PDF). In Peter Forster; Colin Renfrew (eds.). Phylogenetic Methods and the Prehistory of Languages. McDonald Institute Monographs. McDonald Institute for Archaeological Research.
Bibliography[]
- Schuh, Randall T.; Brower, Andrew V.Z. (2009). Biological Systematics: principles and applications (2nd ed.). Ithaca: Comstock Pub. Associates/Cornell University Press. ISBN 978-0-8014-4799-0. OCLC 312728177.
- Forster, Peter; Renfrew, Colin, eds. (2006). Phylogenetic Methods and the Prehistory of Languages. McDonald Institute Press, University of Cambridge. ISBN 978-1-902937-33-5. OCLC 69733654.
- Baum, David A.; Smith, Stacey D. (2013). Tree Thinking: an introduction to phylogenetic biology. Greenwood Village, CO: Roberts and Company. ISBN 978-1-936221-16-5. OCLC 767565978.
- Stuessy, Tod F. (2009). Plant Taxonomy: The Systematic Evaluation of Comparative Data. Columbia University Press. ISBN 978-0-231-14712-5.
External links[]
- The dictionary definition of phylogenetics at Wiktionary
- Phylogenetics