Resumen
| Idioma original | Inglés estadounidense |
|---|---|
| Páginas (desde-hasta) | 1090-1100 |
| Número de páginas | 11 |
| Publicación | Evolution |
| Volumen | 63 |
| N.º | 4 |
| DOI | |
| Estado | Publicada - abr. 2009 |
Huella
Profundice en los temas de investigación de 'Phylogenetic analysis of the evolutionary correlation using likelihood'. En conjunto forman una huella única.Citar esto
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En: Evolution, Vol. 63, N.º 4, 04.2009, p. 1090-1100.
Producción científica: Contribución a una revista › Artículo › revisión exhaustiva
TY - JOUR
T1 - Phylogenetic analysis of the evolutionary correlation using likelihood
AU - Revell, L.J.
AU - Collar, D.C.
N1 - Cited By :60 Export Date: 17 April 2018 CODEN: EVOLA Correspondence Address: Revell, L. J.; Department of Organismic and Evolutionary Biology, Harvard University, Cambridge, MA 02138, United States; email: lrevell@fas.harvard.edu References: Akaike, H., A new look at the statistical model identification (1974) IEEE Trans. Automat. Control, 6, pp. 716-723; Arnold, S.J., Pfrender, M.E., Jones, A.G., The adaptive landscape as a conceptual bridge between micro- and macroevolution (2001) Genetica, 112-113, pp. 9-32; Bégin, M., Roff, D.A., From micro- to macroevolution through quantitative genetic variation: Positive evidence from field crickets (2004) Evolution, 58, pp. 2287-2304; Bollback, J.P., SIMMAP: Stochastic character mapping of discrete traits on phylogenies (2006) BMC Bioinform., 7, p. 88; Burnham, K.P., Anderson, D.R., (2002) Model Selection and Multimodel Inference: A Practical Information-theoretic Approach., , and. 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Biol., 52, pp. 131-158; Hulsey, C.D., García De León, F.J., Rodiles-Hernández, R., Micro- and macroevolutionary decoupling of cichlid jaws: A test of Liem's key innovation hypothesis (2006) Evolution, 60, pp. 2096-2109; Hunter, J.P., Key innovations and the ecology of macroevolution (1998) Trends Ecol. Evol., 13, pp. 31-36; Hurvich, C.M., Tsai, C.-L., Regression and time series model selection in small samples (1989) Biometrika, 76, pp. 297-307; Jones, A.G., Arnold, S.J., Bürger, R., Stability of the G-matrix in a population experiencing pleiotropic mutation, stabilizing selection, and genetic drift (2003) Evolution, 57, pp. 1747-1760; Jones, A.G., Arnold, S.J., Bürger, R., The mutation matrix and the evolution of evolvability (2007) Evolution, 61, pp. 727-745; Lande, R., Quantitative genetic analysis of multivariate evolution, applied to brain:body size allometry (1979) Evolution, 33, pp. 402-416; Lauder, G.V., Form and function: Structural analysis in evolutionary morphology (1981) Paleobiology, 7, pp. 430-442; Liem, K.F., Evolutionary strategies and morphological innovations: Cichlid pharyngeal jaws (1973) Syst. Zool., 22, pp. 425-441; Martins, E.P., Estimating the rate of phenotypic evolution from comparative data (1994) Am. 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Carl Winter, Heidelberg, Germany; Near, T.J., Bolnick, D.I., Wainwright, P.C., Fossil calibrations and molecular divergence time estimates in centrarchid fishes (Teleostei: Centrarchidae) (2005) Evolution, 59, pp. 1768-1782; 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; Pagel, M., Inferring the historical patterns of biological evolution (1999) Nature, 401, pp. 877-884; Phillips, P.C., Arnold, S.J., Hierarchical comparison of genetic variance-covariance matrices. I. Using the Flury hierarchy (1999) Evolution, 53, pp. 1506-1515; Quinn, G.P., Keough, M.J., (2002) Experimental Design and Data Analysis for Biologists., , and. Cambridge Univ. Press, Cambridge, U.K; Revell, L.J., The G matrix under fluctuating correlational mutation and selection (2007) Evolution, 61, pp. 1857-1872; 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., 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., Harrison, A.S., PCCA: A program for phylogenetic canonical correlation analysis (2008) Bioinformatics, 24, pp. 1018-1020; Roff, D.A., (1997) Evolutionary Quantitative Genetics., , Chapman & Hall, New York; Rohlf, F.J., Comparative methods for the analysis of continuous variables: Geometric interpretations (2001) Evolution, 55, pp. 2143-2160; Schluter, D., Character displacement and the adaptive divergence of finches on islands and continents (1988) Am. Nat., 131, pp. 799-824; Sokal, R.R., Rohlf, F.J., (1995) Biometry: The Principles and Practice of Statistics in Biological Research. 3rd Ed., , and. W. H. Freeman and Company, New York; Steppan, S.J., Phillips, P.C., Houle, D., Comparative quantitative genetics: Evolution of the G matrix (2002) Trends Ecol. Evol., 17, pp. 320-327; Stock, D.W., The genetic basis of modularity in the development and evolution of the vertebrate dentition (2001) Phil. Trans. R. Soc. Lond. B, 356, pp. 1633-1653; Strathmann, R.R., Jahn, T.L., Fonseca, J.R.C., Suspension feeding by marine invertebrate larvae: Clearance of particles by ciliated bands of a rotifer, pluteus, and trochophone (1972) Biol. Bull., 142, pp. 505-519; Thomas, G.H., Freckleton, R.P., Székely, T., Comparative analysis of the influence of developmental mode on phenotypic diversification rates in shorebirds (2006) Proc. R. Soc. B, 273, pp. 1619-1624; Vermeij, G.J., Adaptation, versatility, and evolution (1973) Syst. Zool., 22, pp. 466-477; Walker, J.A., A general model of functional constraints on phenotypic evolution (2007) Am. Nat., 170, pp. 681-689; Walker Jr., W.F., (1987) Functional Anatomy of the Vertebrates: An Evolutionary Perspective., , Saunders College Publishing, Philadelphia, PA; Whitlock, M.C., Phillips, P.C., Fowler, K., Persistence of changes in the genetic covariance matrix after a bottleneck Evolution, 56, pp. 1968-1975
PY - 2009/4
Y1 - 2009/4
N2 - Many evolutionary processes can lead to a change in the correlation between continuous characters over time or on different branches of a phylogenetic tree. Shifts in genetic or functional constraint, in the selective regime, or in some combination thereof can influence both the evolution of continuous traits and their relation to each other. These changes can often be mapped on a phylogenetic tree to examine their influence on multivariate phenotypic diversification. We propose a new likelihood method to fit multiple evolutionary rate matrices (also called evolutionary variance-covariance matrices) to species data for two or more continuous characters and a phylogeny. The evolutionary rate matrix is a matrix containing the evolutionary rates for individual characters on its diagonal, and the covariances between characters (of which the evolutionary correlations are a function) elsewhere. To illustrate our approach, we apply the method to an empirical dataset consisting of two features of feeding morphology sampled from 28 centrarchid fish species, as well as to data generated via phylogenetic numerical simulations. We find that the method has appropriate type I error, power, and parameter estimation. The approach presented herein is the first to allow for the explicit testing of how and when the evolutionary covariances between characters have changed in the history of a group. © 2009 The Author(s).
AB - Many evolutionary processes can lead to a change in the correlation between continuous characters over time or on different branches of a phylogenetic tree. Shifts in genetic or functional constraint, in the selective regime, or in some combination thereof can influence both the evolution of continuous traits and their relation to each other. These changes can often be mapped on a phylogenetic tree to examine their influence on multivariate phenotypic diversification. We propose a new likelihood method to fit multiple evolutionary rate matrices (also called evolutionary variance-covariance matrices) to species data for two or more continuous characters and a phylogeny. The evolutionary rate matrix is a matrix containing the evolutionary rates for individual characters on its diagonal, and the covariances between characters (of which the evolutionary correlations are a function) elsewhere. To illustrate our approach, we apply the method to an empirical dataset consisting of two features of feeding morphology sampled from 28 centrarchid fish species, as well as to data generated via phylogenetic numerical simulations. We find that the method has appropriate type I error, power, and parameter estimation. The approach presented herein is the first to allow for the explicit testing of how and when the evolutionary covariances between characters have changed in the history of a group. © 2009 The Author(s).
U2 - 10.1111/j.1558-5646.2009.00616.x
DO - 10.1111/j.1558-5646.2009.00616.x
M3 - Article
SN - 0014-3820
VL - 63
SP - 1090
EP - 1100
JO - Evolution
JF - Evolution
IS - 4
ER -