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Homoplasy

February 16, 2024

Not to be confused with Homoplasmy.

Homoplasy, in biology and phylogenetics, is the term used to describe a feature that has been gained or lost independently in separate lineages over the course of evolution. This is different from homology, which is the term used to characterize the similarity of features that can be parsimoniously explained by common ancestry.[1] Homoplasy can arise from both similar selection pressures acting on adapting species, and the effects of genetic drift.[2][3]

Homoplasy is the similarity in a feature that is not parsimoniously explained by descent from a common ancestor.

Most often, homoplasy is viewed as a similarity in morphological characters. However, homoplasy may also appear in other character types, such as similarity in the genetic sequence,[4][5] life cycle types[6] or even behavioral traits.[7][5]

Etymology edit

The term homoplasy was first used by Ray Lankester in 1870.[8] The corresponding adjective is either homoplasic or homoplastic. It is derived from the two Ancient Greek words ὁμός (homós), meaning "similar, alike, the same", and πλάσσω (plássō), meaning "to shape, to mold".[9][10][11][4]

Parallelism and convergence edit

Parallel and convergent evolution lead to homoplasy when different species independently evolve or gain apparently identical features, which are different from the feature inferred to have been present in their common ancestor. When the similar features are caused by an equivalent developmental mechanism, the process is referred to as parallel evolution.[12][13] The process is called convergent evolution when the similarity arises from different developmental mechanisms.[13][14] These types of homoplasy may occur when different lineages live in comparable ecological niches that require similar adaptations for an increase in fitness. An interesting example is that of the marsupial moles (Notoryctidae), golden moles (Chrysochloridae) and northern moles (Talpidae). These are mammals from different geographical regions and lineages, and have all independently evolved very similar burrowing characteristics (such as cone-shaped heads and flat frontal claws) to live in a subterranean ecological niche.[15]

Reversion edit

In contrast, reversal (a.k.a. vestigialization) leads to homoplasy through the disappearance of previously gained features.[16] This process may result from changes in the environment in which certain gained characteristics are no longer relevant, or have even become costly.[17][3] This can be observed in subterranean and cave-dwelling animals by their loss of sight,[15][18] in cave-dwelling animals through their loss of pigmentation,[18] and in both snakes and legless lizards through their loss of limbs.[19][20]

Distinguishing homology from homoplasy edit

Homoplasy, especially the type that occurs in more closely related phylogenetic groups, can make phylogenetic analysis more challenging. Phylogenetic trees are often selected by means of parsimony analysis.[21][22] These analyses can be done with phenotypic characters, as well as DNA sequences.[23] Using parsimony analysis, the hypothesis of relationships that requires the fewest (or least costly) character state transformations is preferred over alternative hypotheses. Evaluation of these trees may become a challenge when clouded by the occurrence of homoplasy in the characters used for the analysis. The most important approach to overcoming these challenges is to increase the number of independent (non-pleiotropic, non-linked) characteristics used in the phylogenetic analysis. Along with parsimony analysis, one could perform a likelihood analysis, where the most likely tree, given a particular model of evolution, is selected, and branch lengths are inferred.

According to the cladistic interpretation, homoplasy is invoked when the distribution of a character state cannot be explained parsimoniously (without extra inferred character state transformations between the terminals and their ancestral node) on a preferred phylogenetic hypothesis - that is, the feature in question arises (or disappears) at more than one point on the tree.[16]

In the case of DNA sequences, homoplasy is very common due to the redundancy of the genetic code. An observed homoplasy may simply be the result of random nucleotide substitutions accumulating over time, and thus may not need an adaptationist evolutionary explanation.[5]

Examples and applications of homoplasy edit

There are numerous documented examples of homoplasy within the following taxa:

The occurrence of homoplasy can also be used to make predictions about evolution. Recent studies have used homoplasy to predict the possibility and the path of extraterrestrial evolution. For example, Levin et al. (2017) suggest that the development of eye-like structures is highly likely, due to its numerous, independently evolved incidences on earth.[16][32]

Homoplasy vs. evolutionary contingency edit

In his book Wonderful Life, Stephen Jay Gould claims that repeating the evolutionary process, from any point in time onward, would not produce the same results.[33] The occurrence of homoplasy is viewed by some biologists as an argument against Gould’s theory of evolutionary contingency. Powell & Mariscal (2015) argue that this disagreement is caused by an equivocation and that both the theory of contingency and homoplastic occurrence can be true at the same time.[34]

See also edit

References edit

  1. ^ Torres-Montúfar A, Borsch T, Ochoterena H (May 2018). "When Homoplasy Is Not Homoplasy: Dissecting Trait Evolution by Contrasting Composite and Reductive Coding". Systematic Biology. 67 (3): 543–551. doi:10.1093/sysbio/syx053. PMID 28645204.
  2. ^ Stearns SC, Hoekstra RF (2005). Evolution: an introduction (2nd ed.). Oxford: Oxford University Press. ISBN 9780199255634.
  3. ^ a b Hall AR, Colegrave N (March 2008). "Decay of unused characters by selection and drift". Journal of Evolutionary Biology. 21 (2): 610–7. doi:10.1111/j.1420-9101.2007.01473.x. PMID 18081745. S2CID 11165522.
  4. ^ a b Reece JB, Urry LA, Cain ML, Wasserman SA, Minorsky PV, Jackson RB (2011). Campbell Biology (9th ed.). Pearson. ISBN 9780321739759.
  5. ^ a b c Sanderson MJ, Hufford L (1996). Homoplasy: The Recurrence of Similarity in Evolution. San Diego, CA: Academic Press, Inc. ISBN 0-12-618030-X.
  6. ^ Silberfeld T, Leigh JW, Verbruggen H, Cruaud C, de Reviers B, Rousseau F (August 2010). "A multi-locus time-calibrated phylogeny of the brown algae (Heterokonta, Ochrophyta, Phaeophyceae): Investigating the evolutionary nature of the "brown algal crown radiation"". Molecular Phylogenetics and Evolution. 56 (2): 659–74. doi:10.1016/j.ympev.2010.04.020. PMID 20412862.
  7. ^ de Queiroz A, Wimberger PH (February 1993). "The usefulness of behavior for phylogeny estimation: levels of homoplasy in behavioral and morphological characters". Evolution; International Journal of Organic Evolution. 47 (1): 46–60. doi:10.1111/j.1558-5646.1993.tb01198.x. PMID 28568085. S2CID 205778379.
  8. ^ Lankester ER (1870). "On the use of the term homology in modern zoology, and the distinction between homogenetic and homoplastic agreements". Annals and Magazine of Natural History. 6 (31): 34–43. doi:10.1080/00222937008696201.
  9. ^ Bailly A (1981-01-01). Abrégé du dictionnaire grec français. Paris: Hachette. ISBN 2010035283. OCLC 461974285.
  10. ^ Bailly A. "Greek-french dictionary online". www.tabularium.be. Retrieved October 25, 2018.
  11. ^ Holt JR, Judica CA (February 4, 2014). . Archived from the original on July 1, 2017. Retrieved September 21, 2018.
  12. ^ Archie JW (1989). "Homoplasy excess ratios: new indices for measuring levels of homoplasy in phylogenetic systematics and a critique of the consistency index". Systematic Biology. 38 (3): 253–269. doi:10.2307/2992286. JSTOR 2992286.
  13. ^ a b Wake DB (September 1991). "Homoplasy: The Result of Natural Selection, or Evidence of Design Limitations?". The American Naturalist. 138 (3): 543–567. doi:10.1086/285234. S2CID 85043463.
  14. ^ Hodin J (2000). "Plasticity and constraints in development and evolution". Journal of Experimental Zoology. 288 (1): 1–20. doi:10.1002/(SICI)1097-010X(20000415)288:1<1::AID-JEZ1>3.0.CO;2-7. PMID 10750048.
  15. ^ a b Nevo E (1979). "Adaptive convergence and divergence of subterranean mammals". Annual Review of Ecology and Systematics. 10: 269–308. doi:10.1146/annurev.es.10.110179.001413.
  16. ^ a b c Wake DB, Wake MH, Specht CD (February 2011). "Homoplasy: from detecting pattern to determining process and mechanism of evolution". Science. 331 (6020): 1032–5. Bibcode:2011Sci...331.1032W. doi:10.1126/science.1188545. PMID 21350170. S2CID 26845473.
  17. ^ Fong DW, Kane TC, Culver DC (1995). "Vestigialization and loss of nonfunctional characters". Annual Review of Ecology and Systematics. 26: 249–68. doi:10.1146/annurev.es.26.110195.001341.
  18. ^ a b Jones R, Culver DC (May 1989). "Evidence for selection on sensory structures in a cave population of Gammarus minus (Amphipoda)". Evolution; International Journal of Organic Evolution. 43 (3): 688–693. doi:10.1111/j.1558-5646.1989.tb04267.x. PMID 28568387. S2CID 32245717.
  19. ^ Skinner A, Lee MS (2009). "Body-form evolution in the scincid lizard Lerista and the mode of macroevolutionary transitions". Evolutionary Biology. 36: 292–300. doi:10.1007/s11692-009-9064-9. S2CID 42060285.
  20. ^ Skinner A, Lee MS, Hutchinson MN (November 2008). "Rapid and repeated limb loss in a clade of scincid lizards". BMC Evolutionary Biology. 8: 310. doi:10.1186/1471-2148-8-310. PMC 2596130. PMID 19014443.
  21. ^ Wiley EO, Lieberman BS (2011). Phylogenetics: Theory and Practice of Phylogenetic Systematics. Hoboken, NJ: John Wiley & Sons, Inc. ISBN 9780470905968.
  22. ^ Schuh RT, Brower AV (2009). Biological Systematics: Principles and Applications. Ithaca, NY: Cornell University Press. ISBN 9780801462436.
  23. ^ Felsenstein J (2004). Inferring phylogenies. Sinauer. ISBN 978-0878931774.
  24. ^ Verheye ML, Martin P, Backeljau T, D'Udekem D'Acoz C (2015-12-22). "DNA analyses reveal abundant homoplasy in taxonomically important morphological characters of Eusiroidea (Crustacea, Amphipoda)". Zoologica Scripta. 45 (3): 300–321. doi:10.1111/zsc.12153. S2CID 86052388.
  25. ^ Wu ZY, Milne RI, Chen CJ, Liu J, Wang H, Li DZ (2015-11-03). "Ancestral State Reconstruction Reveals Rampant Homoplasy of Diagnostic Morphological Characters in Urticaceae, Conflicting with Current Classification Schemes". PLOS ONE. 10 (11): e0141821. Bibcode:2015PLoSO..1041821W. doi:10.1371/journal.pone.0141821. PMC 4631448. PMID 26529598.
  26. ^ Mejías JA, Chambouleyron M, Kim SH, Infante MD, Kim SC, Léger JF (2018-07-19). "Phylogenetic and morphological analysis of a new cliff-dwelling species reveals a remnant ancestral diversity and evolutionary parallelism in Sonchus (Asteraceae)". Plant Systematics and Evolution. 304 (8): 1023–1040. doi:10.1007/s00606-018-1523-2. S2CID 49873212.
  27. ^ He L, Schneider H, Hovenkamp P, Marquardt J, Wei R, Wei X, Zhang X, Xiang Q (2018-05-09). "A molecular phylogeny of selligueoid ferns (Polypodiaceae): Implications for a natural delimitation despite homoplasy and rapid radiation". Taxon. 67 (2): 237–249. doi:10.12705/672.1.
  28. ^ Schär S, Talavera G, Espadaler X, Rana JD, Andersen Andersen A, Cover SP, Vila R (2018-06-27). "Do Holarctic ant species exist? Trans-Beringian dispersal and homoplasy in the Formicidae". Journal of Biogeography. 45 (8): 1917–1928. doi:10.1111/jbi.13380. S2CID 51832848.
  29. ^ Henriques R, von der Heyden S, Matthee CA (2016-03-28). "When homoplasy mimics hybridization: a case study of Cape hakes (Merluccius capensis and M. paradoxus)". PeerJ. 4: e1827. doi:10.7717/peerj.1827. PMC 4824878. PMID 27069785.
  30. ^ Ortiz D, Francke OF, Bond JE (October 2018). "A tangle of forms and phylogeny: Extensive morphological homoplasy and molecular clock heterogeneity in Bonnetina and related tarantulas". Molecular Phylogenetics and Evolution. 127: 55–73. doi:10.1016/j.ympev.2018.05.013. PMID 29778724. S2CID 29152043.
  31. ^ Lee MS, Yates AM (June 2018). "Tip-dating and homoplasy: reconciling the shallow molecular divergences of modern gharials with their long fossil record". Proceedings. Biological Sciences. 285 (1881): 20181071. doi:10.1098/rspb.2018.1071. PMC 6030529. PMID 30051855.
  32. ^ Levin SR, Scott TW, Cooper HS, West SA (2017). "Darwin's aliens". International Journal of Astrobiology. 18: 1–9. doi:10.1017/S1473550417000362.
  33. ^ Gould SJ (2000). Wonderful Life: The Burgess Shale and the Nature of History. London: Vintage Books. ISBN 9780099273455.
  34. ^ Powell R, Mariscal C (December 2015). "Convergent evolution as natural experiment: the tape of life reconsidered". Interface Focus. 5 (6): 20150040. doi:10.1098/rsfs.2015.0040. PMC 4633857. PMID 26640647.

February 16, 2024
homoplasy, confused, with, homoplasmy, biology, phylogenetics, term, used, describe, feature, that, been, gained, lost, independently, separate, lineages, over, course, evolution, this, different, from, homology, which, term, used, characterize, similarity, fe. Not to be confused with Homoplasmy Homoplasy in biology and phylogenetics is the term used to describe a feature that has been gained or lost independently in separate lineages over the course of evolution This is different from homology which is the term used to characterize the similarity of features that can be parsimoniously explained by common ancestry 1 Homoplasy can arise from both similar selection pressures acting on adapting species and the effects of genetic drift 2 3 Homoplasy is the similarity in a feature that is not parsimoniously explained by descent from a common ancestor Most often homoplasy is viewed as a similarity in morphological characters However homoplasy may also appear in other character types such as similarity in the genetic sequence 4 5 life cycle types 6 or even behavioral traits 7 5 Contents 1 Etymology 2 Parallelism and convergence 3 Reversion 4 Distinguishing homology from homoplasy 5 Examples and applications of homoplasy 6 Homoplasy vs evolutionary contingency 7 See also 8 ReferencesEtymology editThe term homoplasy was first used by Ray Lankester in 1870 8 The corresponding adjective is either homoplasic or homoplastic It is derived from the two Ancient Greek words ὁmos homos meaning similar alike the same and plassw plassō meaning to shape to mold 9 10 11 4 Parallelism and convergence editParallel and convergent evolution lead to homoplasy when different species independently evolve or gain apparently identical features which are different from the feature inferred to have been present in their common ancestor When the similar features are caused by an equivalent developmental mechanism the process is referred to as parallel evolution 12 13 The process is called convergent evolution when the similarity arises from different developmental mechanisms 13 14 These types of homoplasy may occur when different lineages live in comparable ecological niches that require similar adaptations for an increase in fitness An interesting example is that of the marsupial moles Notoryctidae golden moles Chrysochloridae and northern moles Talpidae These are mammals from different geographical regions and lineages and have all independently evolved very similar burrowing characteristics such as cone shaped heads and flat frontal claws to live in a subterranean ecological niche 15 Reversion editIn contrast reversal a k a vestigialization leads to homoplasy through the disappearance of previously gained features 16 This process may result from changes in the environment in which certain gained characteristics are no longer relevant or have even become costly 17 3 This can be observed in subterranean and cave dwelling animals by their loss of sight 15 18 in cave dwelling animals through their loss of pigmentation 18 and in both snakes and legless lizards through their loss of limbs 19 20 Distinguishing homology from homoplasy editHomoplasy especially the type that occurs in more closely related phylogenetic groups can make phylogenetic analysis more challenging Phylogenetic trees are often selected by means of parsimony analysis 21 22 These analyses can be done with phenotypic characters as well as DNA sequences 23 Using parsimony analysis the hypothesis of relationships that requires the fewest or least costly character state transformations is preferred over alternative hypotheses Evaluation of these trees may become a challenge when clouded by the occurrence of homoplasy in the characters used for the analysis The most important approach to overcoming these challenges is to increase the number of independent non pleiotropic non linked characteristics used in the phylogenetic analysis Along with parsimony analysis one could perform a likelihood analysis where the most likely tree given a particular model of evolution is selected and branch lengths are inferred According to the cladistic interpretation homoplasy is invoked when the distribution of a character state cannot be explained parsimoniously without extra inferred character state transformations between the terminals and their ancestral node on a preferred phylogenetic hypothesis that is the feature in question arises or disappears at more than one point on the tree 16 In the case of DNA sequences homoplasy is very common due to the redundancy of the genetic code An observed homoplasy may simply be the result of random nucleotide substitutions accumulating over time and thus may not need an adaptationist evolutionary explanation 5 Examples and applications of homoplasy editThere are numerous documented examples of homoplasy within the following taxa Eusiroidea crustaceans and Amphipoda 24 Urticaceae 25 Asteraceae 26 Polypodioideae Selligueoid Ferns 27 Ants 28 Merluccius capensis cape hakes 29 Tarantula spiders of the genus Bonnetina nearly all morphological traits within this genus are homoplastic Only sexual features were observed to not be homoplastic suggesting that sexual selection may have been a driving force in the divergence of tarantulas 30 Gharials with homoplasy between Tomistoma and true crocodiles and between Thoracosaurus and Gavialis 31 The occurrence of homoplasy can also be used to make predictions about evolution Recent studies have used homoplasy to predict the possibility and the path of extraterrestrial evolution For example Levin et al 2017 suggest that the development of eye like structures is highly likely due to its numerous independently evolved incidences on earth 16 32 Homoplasy vs evolutionary contingency editIn his book Wonderful Life Stephen Jay Gould claims that repeating the evolutionary process from any point in time onward would not produce the same results 33 The occurrence of homoplasy is viewed by some biologists as an argument against Gould s theory of evolutionary contingency Powell amp Mariscal 2015 argue that this disagreement is caused by an equivocation and that both the theory of contingency and homoplastic occurrence can be true at the same time 34 See also editConvergent evolution Incomplete lineage sorting Heteroplasmy Homology biology References edit Torres Montufar A Borsch T Ochoterena H May 2018 When Homoplasy Is Not Homoplasy Dissecting Trait Evolution by Contrasting Composite and Reductive Coding Systematic Biology 67 3 543 551 doi 10 1093 sysbio syx053 PMID 28645204 Stearns SC Hoekstra RF 2005 Evolution an introduction 2nd ed Oxford Oxford University Press ISBN 9780199255634 a b Hall AR Colegrave N March 2008 Decay of unused characters by selection and drift Journal of Evolutionary Biology 21 2 610 7 doi 10 1111 j 1420 9101 2007 01473 x PMID 18081745 S2CID 11165522 a b Reece JB Urry LA Cain ML Wasserman SA Minorsky PV Jackson RB 2011 Campbell Biology 9th ed Pearson ISBN 9780321739759 a b c Sanderson MJ Hufford L 1996 Homoplasy The Recurrence of Similarity in Evolution San Diego CA Academic Press Inc ISBN 0 12 618030 X Silberfeld T Leigh JW Verbruggen H Cruaud C de Reviers B Rousseau F August 2010 A multi locus time calibrated phylogeny of the brown algae Heterokonta Ochrophyta Phaeophyceae Investigating the evolutionary nature of the brown algal crown radiation Molecular Phylogenetics and Evolution 56 2 659 74 doi 10 1016 j ympev 2010 04 020 PMID 20412862 de Queiroz A Wimberger PH February 1993 The usefulness of behavior for phylogeny estimation levels of homoplasy in behavioral and morphological characters Evolution International Journal of Organic Evolution 47 1 46 60 doi 10 1111 j 1558 5646 1993 tb01198 x PMID 28568085 S2CID 205778379 Lankester ER 1870 On the use of the term homology in modern zoology and the distinction between homogenetic and homoplastic agreements Annals and Magazine of Natural History 6 31 34 43 doi 10 1080 00222937008696201 Bailly A 1981 01 01 Abrege du dictionnaire grec francais Paris Hachette ISBN 2010035283 OCLC 461974285 Bailly A Greek french dictionary online www tabularium be Retrieved October 25 2018 Holt JR Judica CA February 4 2014 Systematic Biology Dictionary of Terms Homoplasy Archived from the original on July 1 2017 Retrieved September 21 2018 Archie JW 1989 Homoplasy excess ratios new indices for measuring levels of homoplasy in phylogenetic systematics and a critique of the consistency index Systematic Biology 38 3 253 269 doi 10 2307 2992286 JSTOR 2992286 a b Wake DB September 1991 Homoplasy The Result of Natural Selection or Evidence of Design Limitations The American Naturalist 138 3 543 567 doi 10 1086 285234 S2CID 85043463 Hodin J 2000 Plasticity and constraints in development and evolution Journal of Experimental Zoology 288 1 1 20 doi 10 1002 SICI 1097 010X 20000415 288 1 lt 1 AID JEZ1 gt 3 0 CO 2 7 PMID 10750048 a b Nevo E 1979 Adaptive convergence and divergence of subterranean mammals Annual Review of Ecology and Systematics 10 269 308 doi 10 1146 annurev es 10 110179 001413 a b c Wake DB Wake MH Specht CD February 2011 Homoplasy from detecting pattern to determining process and mechanism of evolution Science 331 6020 1032 5 Bibcode 2011Sci 331 1032W doi 10 1126 science 1188545 PMID 21350170 S2CID 26845473 Fong DW Kane TC Culver DC 1995 Vestigialization and loss of nonfunctional characters Annual Review of Ecology and Systematics 26 249 68 doi 10 1146 annurev es 26 110195 001341 a b Jones R Culver DC May 1989 Evidence for selection on sensory structures in a cave population of Gammarus minus Amphipoda Evolution International Journal of Organic Evolution 43 3 688 693 doi 10 1111 j 1558 5646 1989 tb04267 x PMID 28568387 S2CID 32245717 Skinner A Lee MS 2009 Body form evolution in the scincid lizard Lerista and the mode of macroevolutionary transitions Evolutionary Biology 36 292 300 doi 10 1007 s11692 009 9064 9 S2CID 42060285 Skinner A Lee MS Hutchinson MN November 2008 Rapid and repeated limb loss in a clade of scincid lizards BMC Evolutionary Biology 8 310 doi 10 1186 1471 2148 8 310 PMC 2596130 PMID 19014443 Wiley EO Lieberman BS 2011 Phylogenetics Theory and Practice of Phylogenetic Systematics Hoboken NJ John Wiley amp Sons Inc ISBN 9780470905968 Schuh RT Brower AV 2009 Biological Systematics Principles and Applications Ithaca NY Cornell University Press ISBN 9780801462436 Felsenstein J 2004 Inferring phylogenies Sinauer ISBN 978 0878931774 Verheye ML Martin P Backeljau T D Udekem D Acoz C 2015 12 22 DNA analyses reveal abundant homoplasy in taxonomically important morphological characters of Eusiroidea Crustacea Amphipoda Zoologica Scripta 45 3 300 321 doi 10 1111 zsc 12153 S2CID 86052388 Wu ZY Milne RI Chen CJ Liu J Wang H Li DZ 2015 11 03 Ancestral State Reconstruction Reveals Rampant Homoplasy of Diagnostic Morphological Characters in Urticaceae Conflicting with Current Classification Schemes PLOS ONE 10 11 e0141821 Bibcode 2015PLoSO 1041821W doi 10 1371 journal pone 0141821 PMC 4631448 PMID 26529598 Mejias JA Chambouleyron M Kim SH Infante MD Kim SC Leger JF 2018 07 19 Phylogenetic and morphological analysis of a new cliff dwelling species reveals a remnant ancestral diversity and evolutionary parallelism in Sonchus Asteraceae Plant Systematics and Evolution 304 8 1023 1040 doi 10 1007 s00606 018 1523 2 S2CID 49873212 He L Schneider H Hovenkamp P Marquardt J Wei R Wei X Zhang X Xiang Q 2018 05 09 A molecular phylogeny of selligueoid ferns Polypodiaceae Implications for a natural delimitation despite homoplasy and rapid radiation Taxon 67 2 237 249 doi 10 12705 672 1 Schar S Talavera G Espadaler X Rana JD Andersen Andersen A Cover SP Vila R 2018 06 27 Do Holarctic ant species exist Trans Beringian dispersal and homoplasy in the Formicidae Journal of Biogeography 45 8 1917 1928 doi 10 1111 jbi 13380 S2CID 51832848 Henriques R von der Heyden S Matthee CA 2016 03 28 When homoplasy mimics hybridization a case study of Cape hakes Merluccius capensis and M paradoxus PeerJ 4 e1827 doi 10 7717 peerj 1827 PMC 4824878 PMID 27069785 Ortiz D Francke OF Bond JE October 2018 A tangle of forms and phylogeny Extensive morphological homoplasy and molecular clock heterogeneity in Bonnetina and related tarantulas Molecular Phylogenetics and Evolution 127 55 73 doi 10 1016 j ympev 2018 05 013 PMID 29778724 S2CID 29152043 Lee MS Yates AM June 2018 Tip dating and homoplasy reconciling the shallow molecular divergences of modern gharials with their long fossil record Proceedings Biological Sciences 285 1881 20181071 doi 10 1098 rspb 2018 1071 PMC 6030529 PMID 30051855 Levin SR Scott TW Cooper HS West SA 2017 Darwin s aliens International Journal of Astrobiology 18 1 9 doi 10 1017 S1473550417000362 Gould SJ 2000 Wonderful Life The Burgess Shale and the Nature of History London Vintage Books ISBN 9780099273455 Powell R Mariscal C December 2015 Convergent evolution as natural experiment the tape of life reconsidered Interface Focus 5 6 20150040 doi 10 1098 rsfs 2015 0040 PMC 4633857 PMID 26640647 Retrieved from https en wikipedia org w index php title Homoplasy amp oldid 1207305629, wikipedia, wiki, book, books, library,

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