Ancestral character estimation under the threshold model from quantitative genetics

L.J. Revell

doi:10.1111/evo.12300

Ancestral character estimation under the threshold model from quantitative genetics

L.J. Revell

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97 Citas (Scopus)

Resumen

Evolutionary biology is a study of life's history on Earth. In researching this history, biologists are often interested in attempting to reconstruct phenotypes for the long extinct ancestors of living species. Various methods have been developed to do this on a phylogeny from the data for extant taxa. In the present article, I introduce a new approach for ancestral character estimation for discretely valued traits. This approach is based on the threshold model from evolutionary quantitative genetics. Under the threshold model, the value exhibited by an individual or species for a discrete character is determined by an underlying, unobserved continuous trait called "liability." In this new method for ancestral state reconstruction, I use Bayesian Markov chain Monte Carlo (MCMC) to sample the liabilities of ancestral and tip species, and the relative positions of two or more thresholds, from their joint posterior probability distribution. Using data simulated under the model, I find that the method has very good performance in ancestral character estimation. Use of the threshold model for ancestral state reconstruction relies on a priori specification of the order of the discrete character states along the liability axis. I test the use of a Bayesian MCMC information theoretic criterion based approach to choose among different hypothesized orderings for the discrete character. Finally, I apply the method to the evolution of feeding mode in centrarchid fishes. © 2013 The Society for the Study of Evolution.

Idioma original	Inglés estadounidense
Páginas (desde-hasta)	743-759
Número de páginas	17
Publicación	Evolution
Volumen	68
N.º	3
DOI	https://doi.org/10.1111/evo.12300
Estado	Publicada - oct. 13 2013

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10.1111/evo.12300

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@article{f6d314bd29624c4996e5610a743be0bb,

title = "Ancestral character estimation under the threshold model from quantitative genetics",

abstract = "Evolutionary biology is a study of life's history on Earth. In researching this history, biologists are often interested in attempting to reconstruct phenotypes for the long extinct ancestors of living species. Various methods have been developed to do this on a phylogeny from the data for extant taxa. In the present article, I introduce a new approach for ancestral character estimation for discretely valued traits. This approach is based on the threshold model from evolutionary quantitative genetics. Under the threshold model, the value exhibited by an individual or species for a discrete character is determined by an underlying, unobserved continuous trait called {"}liability.{"} In this new method for ancestral state reconstruction, I use Bayesian Markov chain Monte Carlo (MCMC) to sample the liabilities of ancestral and tip species, and the relative positions of two or more thresholds, from their joint posterior probability distribution. Using data simulated under the model, I find that the method has very good performance in ancestral character estimation. Use of the threshold model for ancestral state reconstruction relies on a priori specification of the order of the discrete character states along the liability axis. I test the use of a Bayesian MCMC information theoretic criterion based approach to choose among different hypothesized orderings for the discrete character. Finally, I apply the method to the evolution of feeding mode in centrarchid fishes. {\textcopyright} 2013 The Society for the Study of Evolution.",

author = "L.J. Revell",

note = "Cited By :29 Export Date: 17 April 2018 CODEN: EVOLA Correspondence Address: Revell, L.J.; Department of Biology, University of Massachusetts Boston, Boston, MA 02125, United States; email: liam.revell@umb.edu References: Akaike, H., A new look at the statistical model identification (1974) IEEE Trans. Autom. Control, 19, pp. 716-723; Beaulieu, J.M., O'Meara, B.C., Donoghue, M.J., Identifying hidden rate changes in the evolution of a binary morphological character: the evolution of plant habit in the campanulid angiosperms (2013) Syst. Biol., 62, pp. 725-737; Bokma, F., Detection of {"}punctuated equilibrium{"} by Bayesian estimation of speciation and extinction rates, ancestral character states, and rates of anagenetic and cladogenetic evolution on a molecular phylogeny (2008) Evolution, 62, pp. 2718-2726; Brooks, D.R., McLennan, D.A., (1991) Phylogeny, ecology, and behavior: a research program in comparative biology, , University of Chicago Press, Chicago, IL; B{\"u}rger, R., Wagner, G.P., Stettinger, F., How much heritable variation can be maintained in finite populations by mutation-selection balance? (1989) Evolution, 43, pp. 1748-1766; Burnham, K.P., Anderson, D.R., (2002) Model selection and multimodel inference: a practical information-theoretic approach, , 2nd ed. Springer, New York, NY; Butler, M.A., King, A.A., Phylogenetic comparative analysis: a modeling approach for adaptive evolution (2004) Am. Nat., 164, pp. 683-695; Cavalli-Sforza, L.L., Edwards, A.W.F., Phylogenetic analysis: models and estimation procedures (1967) Am. J. Hum. Genet., 19, pp. 233-257; Collar, D.C., O'Meara, B.C., Wainwright, P.C., Near, T.J., Piscivory limits diversification of feeding morphology in centrarchid fishes (2009) Evolution, 63, pp. 1557-1573; Cunningham, C.W., Omland, K.E., Oakley, T.H., Reconstructing ancestral character states: a critical reappraisal (1998) Trends Ecol. Evol., 13, pp. 361-366; Eastman, J.M., Alfaro, M.E., Joyce, P., Hipp, A.L., Harmon, L.J., A novel comparative method for identifying shifts in the rate of character evolution on trees (2011) Evolution, 65, pp. 3578-3589; Ekman, S., Andersen, H.L., Wedin, M., The limitations of ancestral state reconstruction and the evolution of the ascus in the Lecanorales (lichenized Ascomycota) (2008) Syst. Biol., 57, pp. 141-156; Felsenstein, J., Maximum likelihood estimation of evolutionary trees from continuous characters (1973) Am. J. Hum. Genet., 25, pp. 471-492; Felsenstein, J., Phylogenies and the comparative method (1985) Am. Nat., 125, pp. 1-15; Felsenstein, J., Phylogenies and quantitative characters (1988) Annu. Rev. Ecol. Syst., 19, pp. 445-471; Felsenstein, J., (2004) Inferring phylogenies, , Sinauer, Sunderland, MA; Felsenstein, J., Using the quantitative genetic threshold model for inferences between and within species (2005) Philos. Trans. R. Soc. Lond. B, 360, pp. 1427-1434; Felsenstein, J., A comparative method for both discrete and continuous characters using the threshold model (2012) Am. Nat., 179, pp. 145-156; Fitzjohn, R.G., Quantitative traits and diversification (2010) Syst. Biol., 59, pp. 619-633; Geweke, J., Evaluating the accuracy of sampling-based approaches to the calculation of posterior moments (1992) Bayesian Statistics, 4. , J. M. Bernado, J. O. Berger, A. P. Dawid, and A. F. M. Smith, eds. Clarendon Press, Oxford, UK; Goldberg, E.E., Igi{\'c}, B., On phylogenetic tests of irreversible evolution (2008) Evolution, 62, pp. 2727-2741; Hansen, T.F., Stabilizing selection and the comparative analysis of adaptation (1997) Evolution, 51, pp. 1341-1351; Harvey, P.H., Pagel, M.D., (1991) The comparative method in evolutionary biology, , Oxford Univ. Press, Oxford, UK; Huelsenbeck, J.P., Bollback, J.P., Empirical and hierarchical Bayesian estimation of ancestral states (2001) Syst. Biol., 50, pp. 351-366; Huelsenbeck, J.P., Nielsen, R., Bollback, J.P., Stochastic mapping of morphological characters (2003) Syst. Biol., 52, pp. 131-158; Ives, A.R., Garland Jr., T., Phylogenetic logistic regression for binary dependent variables (2010) Syst. Biol., 59, pp. 9-26; Jukes, T.H., Cantor, C.R., Evolution of protein molecules (1969) Mammalian protein metabolism, 3, pp. 21-132. , M. N. Murno, ed. Academic Press, New York, NY; Lewis, P.O., A likelihood approach to estimating phylogeny from discrete morphological character data (2001) Syst. Biol., 50, pp. 913-925; Losos, J.B., Uncertainty in the reconstruction of ancestral character states and limitations on the use of phylogenetic comparative methods (1999) Anim. Behav., 58, pp. 1319-1324; Losos, J.B., (2009) Lizards in an evolutionary tree: ecology and adaptive radiation of anoles, , University of California Press, Berkeley, CA; Losos, J.B., Warheit, K.I., Schoener, T.W., Adaptive differentiation following experimental island colonization in Anolis lizards (1997) Nature, 387, pp. 70-73; Lynch, M., Walsh, B., Genetics and the analysis of quantitative traits (1998), Sinauer, Sunderland, MA; Maddison, W.P., Midford, P.E., Otto, S.P., Estimating a binary character's effect on speciation and extinction (2007) Syst. Biol., 56, pp. 701-710; Metropolis, N., Rosenbluth, A.W., Rosenbluth, M.N., Teller, A.H., Equations of state calculations by fast computing machines (1953) J. Chem. Phys., 21, pp. 1087-1092; Near, T.J., Bolnick, D.I., Wainwright, P.C., Fossil calibrations and molecular divergence time estimates in the centrarchid fishes (Teleostei: Centrarchidae) (2005) Evolution, 59, pp. 1768-1782; Nielsen, R., Mapping mutations on phylogenies (2002) Syst. Biol., 51, pp. 729-739; Nunn, C.L., (2011) The comparative approach in evolutionary anthropology and biology, , University of Chicago Press, Chicago, IL; O'Meara, B.C., An{\'e}, C., Sanderson, M.J., Wainwright, P.C., Testing for different rates of continuous trait evolution using likelihood (2006) Evolution, 60, pp. 922-933; Omland, K.E., The assumptions and challenges of ancestral state reconstructions (1999) Syst. Biol., 48, pp. 604-611; Pagel, M., Detecting correlated evolution on phylogenies: a general method for the comparative analysis of discrete characters (1994) Proc. R. Soc. Lond. B, 255, pp. 37-45; Pagel, M., The maximum likelihood approach to reconstructing ancestral character states of discrete characters on phylogenies (1999) Syst. Biol, 48, pp. 612-622; Pagel, M., Meade, A., Barker, D., Bayesian estimation of ancestral character states on phylogenies (2004) Syst. Biol., 53, pp. 673-684; Paradis, E., (2012) Analysis of phylogenetics and evolution with R, , 2nd ed. Springer, New York, NY; Paradis, E., Claude, J., Strimmer, K., APE: analyses of phylogenetics and evolution in R language (2004) Bioinformatics, 20, pp. 289-290; Plummer, M., Best, N., Cowles, K., Vines, K., CODA: convergence diagnosis and output analysis for MCMC (2006) R News, 6, pp. 7-11; (2012) R: a language and environment for statistical computing, , R Core Development Team. R Foundation for Statistical Computing, Vienna, Austria; Rabosky, D.L., Likelihood methods for detecting temporal shifts in diversification rates (2006) Evolution, 60, pp. 1152-1164; Revell, L.J., On the analysis of evolutionary change along single branches in a phylogeny (2008) Am. Nat., 172, pp. 140-147; Revell, L.J., phytools: an R package for phylogenetic comparative biology (and other things) (2012) Methods Ecol. Evol., 3, pp. 217-223; Revell, L.J., Collar, D.C., Phylogenetic analysis of the evolutionary correlation using likelihood (2009) Evolution, 63, pp. 1090-1100; Revell, L.J., Harmon, L.J., Testing quantitative genetic hypotheses about the evolutionary rate matrix for continuous characters (2008) Evol. Ecol. Res., 10, pp. 311-321; Revell, L.J., Mahler, D.L., Peres-Neto, P.R., Redelings, B.D., A new method for identifying exceptional phenotypic diversification (2012) Evolution, 66, pp. 135-146; Rice, W.R., Hostert, E.E., Laboratory experiments on speciation: what have we learned in 40 years? (1993) Evolution, 47, pp. 1637-1653; Rohlf, F.J., Comparative methods for the analysis of continuous variables: geometric interpretations (2001) Evolution, 55, pp. 2143-2160; Ryan, M.J., Rand, A.S., Phylogenetic influence on mating call preference in female t{\'u}ngara frogs, Physalaemus pustulosus (1999) Anim. Behav., 57, pp. 945-956; Schluter, D., Price, T., Mooers, A.O., Ludwig, D., Likelihood of ancestor states in adaptive radiation (1997) Evolution, 51, pp. 1699-1711; Skinner, A., Lee, M.S.Y., Plausibility of inferred ancestral phenotypes and the evaluation of alternative models of limb evolution in scincid lizards (2010) Biol. Lett., 6, pp. 354-358; Spiegelhalter, D.J., Best, N.G., Carlin, B.P., van der Linde, A., Bayesian measures of model complexity and fit (2002) J. R. Stat. Soc. B, 64, pp. 583-639; Stadler, T., Mammalian phylogeny reveals recent diversification rate shifts (2011) Proc. Natl. Acad. Sci. USA, 108, pp. 6187-6192; Viosca, P., A new rock bass from Louisiana and Mississippi (1936) Copeia, 1, pp. 37-45; Wright, S., An analysis of variability in the number of digits in an inbred strain of guinea pigs (1934) Genetics, 19, pp. 506-536; Yang, Z., (2006) Computational molecular evolution, , Oxford Univ. Press: Oxford, UK",

year = "2013",

month = oct,

day = "13",

doi = "10.1111/evo.12300",

language = "English (US)",

volume = "68",

pages = "743--759",

journal = "Evolution",

issn = "0014-3820",

publisher = "Society for the Study of Evolution",

number = "3",

}

TY - JOUR

T1 - Ancestral character estimation under the threshold model from quantitative genetics

AU - Revell, L.J.

N1 - Cited By :29 Export Date: 17 April 2018 CODEN: EVOLA Correspondence Address: Revell, L.J.; Department of Biology, University of Massachusetts Boston, Boston, MA 02125, United States; email: liam.revell@umb.edu References: Akaike, H., A new look at the statistical model identification (1974) IEEE Trans. Autom. Control, 19, pp. 716-723; Beaulieu, J.M., O'Meara, B.C., Donoghue, M.J., Identifying hidden rate changes in the evolution of a binary morphological character: the evolution of plant habit in the campanulid angiosperms (2013) Syst. Biol., 62, pp. 725-737; Bokma, F., Detection of "punctuated equilibrium" by Bayesian estimation of speciation and extinction rates, ancestral character states, and rates of anagenetic and cladogenetic evolution on a molecular phylogeny (2008) Evolution, 62, pp. 2718-2726; Brooks, D.R., McLennan, D.A., (1991) Phylogeny, ecology, and behavior: a research program in comparative biology, , University of Chicago Press, Chicago, IL; Bürger, R., Wagner, G.P., Stettinger, F., How much heritable variation can be maintained in finite populations by mutation-selection balance? (1989) Evolution, 43, pp. 1748-1766; Burnham, K.P., Anderson, D.R., (2002) Model selection and multimodel inference: a practical information-theoretic approach, , 2nd ed. Springer, New York, NY; Butler, M.A., King, A.A., Phylogenetic comparative analysis: a modeling approach for adaptive evolution (2004) Am. Nat., 164, pp. 683-695; Cavalli-Sforza, L.L., Edwards, A.W.F., Phylogenetic analysis: models and estimation procedures (1967) Am. J. Hum. Genet., 19, pp. 233-257; Collar, D.C., O'Meara, B.C., Wainwright, P.C., Near, T.J., Piscivory limits diversification of feeding morphology in centrarchid fishes (2009) Evolution, 63, pp. 1557-1573; Cunningham, C.W., Omland, K.E., Oakley, T.H., Reconstructing ancestral character states: a critical reappraisal (1998) Trends Ecol. Evol., 13, pp. 361-366; Eastman, J.M., Alfaro, M.E., Joyce, P., Hipp, A.L., Harmon, L.J., A novel comparative method for identifying shifts in the rate of character evolution on trees (2011) Evolution, 65, pp. 3578-3589; Ekman, S., Andersen, H.L., Wedin, M., The limitations of ancestral state reconstruction and the evolution of the ascus in the Lecanorales (lichenized Ascomycota) (2008) Syst. Biol., 57, pp. 141-156; Felsenstein, J., Maximum likelihood estimation of evolutionary trees from continuous characters (1973) Am. J. Hum. Genet., 25, pp. 471-492; Felsenstein, J., Phylogenies and the comparative method (1985) Am. Nat., 125, pp. 1-15; Felsenstein, J., Phylogenies and quantitative characters (1988) Annu. Rev. Ecol. Syst., 19, pp. 445-471; Felsenstein, J., (2004) Inferring phylogenies, , Sinauer, Sunderland, MA; Felsenstein, J., Using the quantitative genetic threshold model for inferences between and within species (2005) Philos. Trans. R. Soc. Lond. B, 360, pp. 1427-1434; Felsenstein, J., A comparative method for both discrete and continuous characters using the threshold model (2012) Am. Nat., 179, pp. 145-156; Fitzjohn, R.G., Quantitative traits and diversification (2010) Syst. Biol., 59, pp. 619-633; Geweke, J., Evaluating the accuracy of sampling-based approaches to the calculation of posterior moments (1992) Bayesian Statistics, 4. , J. M. Bernado, J. O. Berger, A. P. Dawid, and A. F. M. Smith, eds. Clarendon Press, Oxford, UK; Goldberg, E.E., Igić, B., On phylogenetic tests of irreversible evolution (2008) Evolution, 62, pp. 2727-2741; Hansen, T.F., Stabilizing selection and the comparative analysis of adaptation (1997) Evolution, 51, pp. 1341-1351; Harvey, P.H., Pagel, M.D., (1991) The comparative method in evolutionary biology, , Oxford Univ. Press, Oxford, UK; Huelsenbeck, J.P., Bollback, J.P., Empirical and hierarchical Bayesian estimation of ancestral states (2001) Syst. Biol., 50, pp. 351-366; Huelsenbeck, J.P., Nielsen, R., Bollback, J.P., Stochastic mapping of morphological characters (2003) Syst. Biol., 52, pp. 131-158; Ives, A.R., Garland Jr., T., Phylogenetic logistic regression for binary dependent variables (2010) Syst. Biol., 59, pp. 9-26; Jukes, T.H., Cantor, C.R., Evolution of protein molecules (1969) Mammalian protein metabolism, 3, pp. 21-132. , M. N. Murno, ed. Academic Press, New York, NY; Lewis, P.O., A likelihood approach to estimating phylogeny from discrete morphological character data (2001) Syst. Biol., 50, pp. 913-925; Losos, J.B., Uncertainty in the reconstruction of ancestral character states and limitations on the use of phylogenetic comparative methods (1999) Anim. Behav., 58, pp. 1319-1324; Losos, J.B., (2009) Lizards in an evolutionary tree: ecology and adaptive radiation of anoles, , University of California Press, Berkeley, CA; Losos, J.B., Warheit, K.I., Schoener, T.W., Adaptive differentiation following experimental island colonization in Anolis lizards (1997) Nature, 387, pp. 70-73; Lynch, M., Walsh, B., Genetics and the analysis of quantitative traits (1998), Sinauer, Sunderland, MA; Maddison, W.P., Midford, P.E., Otto, S.P., Estimating a binary character's effect on speciation and extinction (2007) Syst. Biol., 56, pp. 701-710; Metropolis, N., Rosenbluth, A.W., Rosenbluth, M.N., Teller, A.H., Equations of state calculations by fast computing machines (1953) J. Chem. Phys., 21, pp. 1087-1092; Near, T.J., Bolnick, D.I., Wainwright, P.C., Fossil calibrations and molecular divergence time estimates in the centrarchid fishes (Teleostei: Centrarchidae) (2005) Evolution, 59, pp. 1768-1782; Nielsen, R., Mapping mutations on phylogenies (2002) Syst. Biol., 51, pp. 729-739; Nunn, C.L., (2011) The comparative approach in evolutionary anthropology and biology, , University of Chicago Press, Chicago, IL; O'Meara, B.C., Ané, C., Sanderson, M.J., Wainwright, P.C., Testing for different rates of continuous trait evolution using likelihood (2006) Evolution, 60, pp. 922-933; Omland, K.E., The assumptions and challenges of ancestral state reconstructions (1999) Syst. Biol., 48, pp. 604-611; Pagel, M., Detecting correlated evolution on phylogenies: a general method for the comparative analysis of discrete characters (1994) Proc. R. Soc. Lond. B, 255, pp. 37-45; Pagel, M., The maximum likelihood approach to reconstructing ancestral character states of discrete characters on phylogenies (1999) Syst. Biol, 48, pp. 612-622; Pagel, M., Meade, A., Barker, D., Bayesian estimation of ancestral character states on phylogenies (2004) Syst. Biol., 53, pp. 673-684; Paradis, E., (2012) Analysis of phylogenetics and evolution with R, , 2nd ed. Springer, New York, NY; Paradis, E., Claude, J., Strimmer, K., APE: analyses of phylogenetics and evolution in R language (2004) Bioinformatics, 20, pp. 289-290; Plummer, M., Best, N., Cowles, K., Vines, K., CODA: convergence diagnosis and output analysis for MCMC (2006) R News, 6, pp. 7-11; (2012) R: a language and environment for statistical computing, , R Core Development Team. R Foundation for Statistical Computing, Vienna, Austria; Rabosky, D.L., Likelihood methods for detecting temporal shifts in diversification rates (2006) Evolution, 60, pp. 1152-1164; Revell, L.J., On the analysis of evolutionary change along single branches in a phylogeny (2008) Am. Nat., 172, pp. 140-147; Revell, L.J., phytools: an R package for phylogenetic comparative biology (and other things) (2012) Methods Ecol. Evol., 3, pp. 217-223; Revell, L.J., Collar, D.C., Phylogenetic analysis of the evolutionary correlation using likelihood (2009) Evolution, 63, pp. 1090-1100; Revell, L.J., Harmon, L.J., Testing quantitative genetic hypotheses about the evolutionary rate matrix for continuous characters (2008) Evol. Ecol. Res., 10, pp. 311-321; Revell, L.J., Mahler, D.L., Peres-Neto, P.R., Redelings, B.D., A new method for identifying exceptional phenotypic diversification (2012) Evolution, 66, pp. 135-146; Rice, W.R., Hostert, E.E., Laboratory experiments on speciation: what have we learned in 40 years? (1993) Evolution, 47, pp. 1637-1653; Rohlf, F.J., Comparative methods for the analysis of continuous variables: geometric interpretations (2001) Evolution, 55, pp. 2143-2160; Ryan, M.J., Rand, A.S., Phylogenetic influence on mating call preference in female túngara frogs, Physalaemus pustulosus (1999) Anim. Behav., 57, pp. 945-956; Schluter, D., Price, T., Mooers, A.O., Ludwig, D., Likelihood of ancestor states in adaptive radiation (1997) Evolution, 51, pp. 1699-1711; Skinner, A., Lee, M.S.Y., Plausibility of inferred ancestral phenotypes and the evaluation of alternative models of limb evolution in scincid lizards (2010) Biol. Lett., 6, pp. 354-358; Spiegelhalter, D.J., Best, N.G., Carlin, B.P., van der Linde, A., Bayesian measures of model complexity and fit (2002) J. R. Stat. Soc. B, 64, pp. 583-639; Stadler, T., Mammalian phylogeny reveals recent diversification rate shifts (2011) Proc. Natl. Acad. Sci. USA, 108, pp. 6187-6192; Viosca, P., A new rock bass from Louisiana and Mississippi (1936) Copeia, 1, pp. 37-45; Wright, S., An analysis of variability in the number of digits in an inbred strain of guinea pigs (1934) Genetics, 19, pp. 506-536; Yang, Z., (2006) Computational molecular evolution, , Oxford Univ. Press: Oxford, UK

PY - 2013/10/13

Y1 - 2013/10/13

N2 - Evolutionary biology is a study of life's history on Earth. In researching this history, biologists are often interested in attempting to reconstruct phenotypes for the long extinct ancestors of living species. Various methods have been developed to do this on a phylogeny from the data for extant taxa. In the present article, I introduce a new approach for ancestral character estimation for discretely valued traits. This approach is based on the threshold model from evolutionary quantitative genetics. Under the threshold model, the value exhibited by an individual or species for a discrete character is determined by an underlying, unobserved continuous trait called "liability." In this new method for ancestral state reconstruction, I use Bayesian Markov chain Monte Carlo (MCMC) to sample the liabilities of ancestral and tip species, and the relative positions of two or more thresholds, from their joint posterior probability distribution. Using data simulated under the model, I find that the method has very good performance in ancestral character estimation. Use of the threshold model for ancestral state reconstruction relies on a priori specification of the order of the discrete character states along the liability axis. I test the use of a Bayesian MCMC information theoretic criterion based approach to choose among different hypothesized orderings for the discrete character. Finally, I apply the method to the evolution of feeding mode in centrarchid fishes. © 2013 The Society for the Study of Evolution.

AB - Evolutionary biology is a study of life's history on Earth. In researching this history, biologists are often interested in attempting to reconstruct phenotypes for the long extinct ancestors of living species. Various methods have been developed to do this on a phylogeny from the data for extant taxa. In the present article, I introduce a new approach for ancestral character estimation for discretely valued traits. This approach is based on the threshold model from evolutionary quantitative genetics. Under the threshold model, the value exhibited by an individual or species for a discrete character is determined by an underlying, unobserved continuous trait called "liability." In this new method for ancestral state reconstruction, I use Bayesian Markov chain Monte Carlo (MCMC) to sample the liabilities of ancestral and tip species, and the relative positions of two or more thresholds, from their joint posterior probability distribution. Using data simulated under the model, I find that the method has very good performance in ancestral character estimation. Use of the threshold model for ancestral state reconstruction relies on a priori specification of the order of the discrete character states along the liability axis. I test the use of a Bayesian MCMC information theoretic criterion based approach to choose among different hypothesized orderings for the discrete character. Finally, I apply the method to the evolution of feeding mode in centrarchid fishes. © 2013 The Society for the Study of Evolution.

U2 - 10.1111/evo.12300

DO - 10.1111/evo.12300

M3 - Article

SN - 0014-3820

VL - 68

SP - 743

EP - 759

JO - Evolution

JF - Evolution

IS - 3

ER -

Ancestral character estimation under the threshold model from quantitative genetics

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