Abstract
During the last two decades the role of quantitative genetics in evolutionary theory has expanded considerably. Quantitative genetic-based models addressing long term phenotypic evolution, evolution in multiple environments (phenotypic plasticity) and evolution of ontogenies (developmental trajectories) have been proposed. Yet, the mathematical foundations of quantitative genetics were laid with a very different set of problems in mind (mostly the prediction of short term responses to artificial selection), and at a time in which any details of the genetic machinery were virtually unknown. In this paper we discuss what a model is in population biology, and what kind of model we need in order to address the complexities of phenotypic evolution. We review the assumptions of quantitative genetics and its most recent accomplishments, together with the limitations that such assumptions impose on the modelling of some aspects of phenotypic evolution. We also discuss three alternative appr oaches to the theoretical description of evolutionary trajectories (nonlinear dynamics, complexity theory and optimization theory), and their respective advantages and limitations. We conclude by calling for a new theoretical synthesis, including quantitative genetics and not necessarily limited to the other approaches here discussed.
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REFERENCES
Abrams, P.A., Y. Harada and H. Matsuda (1993). On the relationship between quantitative genetics and ESS models. Evolution 47: 982–985.
Akin, E. (1983). Hopf bifurcation in the two locus genetic model. Memoirs of the American Mathematical Society 284: 1–190.
Altenberg, L. (1991). Chaos from linear frequency-dependent selection. The American Naturalist 138: 51–68.
Arthur, W.B. (1988). Self-reinforcing mechanisms in economics. In: P.W. Anderson, K.J. Arrow and D. Pines, eds., The Economy as an Evolving System. Redwood City CA, Addison-Wesley.
Atchley, W.R. (1987). Developmental quantitative genetics and the evolution of ontogenies. Evolution 41: 316–330.
Atchley, W.R. and B.K. Hall (1991). A model for development and evolution of complex morphological structures. Biological Review 66: 101–157.
Bak, P., C. Tang and K. Wiesenteld (1988). Self-organized criticality. Physical Review A38: 364–374.
Barton, N.H. (1992). On the spread of new gene combinations in the third phase of Wright's shifting-balance. Evolution 46: 551–557.
Barton, N.H. and M. Turelli (1989). Evolutionary quantitative genetics: how little do we know? Annual Review of Genetics 23: 337–370.
Bradshaw, A.D. (1965). Evolutionary significance of phenotypic plasticity in plants. Advances in Genetics 13: 115–155.
Bryant, E.H., S.A. McCommas and L.M. Combs (1986). The effect of an experimental bottleneck upon quantitative genetic variation in the housefly. Genetics 114: 1191–1211.
Campbell, D.R. (1996). Evolution of floral traits in a hermaphroditic plant: field measurements of heritabilities and genetic correlations. Evolution 50: 1442–1453.
Charlesworth, B. (1990). Optimization models, quantitative genetics, and mutation. Evolution 44: 520–538.
Cheverud, J.M., J.J. Rutledge and W.R. Atchley (1983). Quantitative genetics of development: genetic correlations among age-specific trait values and the evolution of ontogeny. Evolution 37: 895–905.
de Jong, G. (1990). Genotype-by-environment interaction and the genetic covariance between environments: multilocus genetics. Genetica 81: 171–177.
Depew, D.J. and B.H. Weber (1995). Darwinism Evolving: Systems Dynamics and the Genealogy of Natural Selection. Cambridge, MA, The MIT Press.
Ebert, D., L. Yampolsky and A.J. van Noordwijk (1993). Genetics of life history in Daphnia magna. II. Phenotypic plasticity. Heredity 70: 344–352.
Emlen, J.M., D.C. Freeman and J.H. Graham (1993). Nonlinear growth dynamics and the origin of fluctuating asymmetry. Genetica 89: 77–96.
Falconer, D.S. (1952). The problem of environment and selection. The American Naturalist 86: 293–298.
Falconer, D.S. (1989). Introduction to Quantitative Genetics. Burnt Hill, Essex, England, Longman.
Falconer, D.S. (1990). Selection in different environments: effects on environmental sensitivity (reaction norm) and on mean performance. Genetical Research 56: 57–70.
Fisher, R.A. (1930). The Genetical Theory of Natural Selection. Oxford, Clarendon.
Futuyma, D.J. (1986). Evolutionary Biology. Sunderland MA, Sinauer.
Gavrilets, S. and A. Hastings (1995). Dynamics of polygenic variability under stabilizing selection, recombination, and drift. Genetical Research 65: 63–74.
Gavrilets, S. and S.M. Scheiner (1993). The genetics of phenotypic plasticity. V. Evolution of reaction norm shape. Journal of Evolutionary Biology 6: 31–48.
Gifford, D.R. and J.S.F. Barker (1991). The nonlincarity of offspring-parent regression for total sternopleural bristle number of Drosophila melanogaster. Theoretical and Applied Genetics 82: 217–220.
Gillespie, J.H. and M. Turelli (1989). Genotype-environment interactions and the maintenance of polygenic variation. Genetics 121: 129–138.
Gomulkiewicz, R. and M. Kirkpatrick (1992). Quantitative genetics and the evolution of reaction norms. Evolution 46: 390–411.
Goodnight, C.J. (1988). Epistasis and the effect of founder events on the additive genetic variance. Evolution 42: 441–454.
Gould, S.J. (1977). Ontogeny and Phylogeny. Cambridge, MA, Harvard University Press.
Gregoire, N. and I. Prigogine (1989). Exploring Complexity. New York, Freeman.
Gromko, M.H. (1995). Unpredictability of correlated response to selection: pleiotropy and sampling interact. Evolution 49: 685–693.
Gulick, D. (1992). Encounters with Chaos. New York, McGraw-Hill.
Gupta, A.P. and R.C. Lewontin (1982). A study of reaction norms in natural populations of Drosophila pseudoobscura. Evolution 36: 934–948.
Hastings, A., C.L. Hom, S. Ellner, P. Turchin and H.C.J. Godfray (1994). Chaos in ecology: is mother nature a strange attractor? Annual Review of Ecology and Systematics 24: 1–33.
Hartl, D.L. and A.G. Clark (1989). Principles of Population Genetics. Sunderland MA, Sinauer.
Holland, J.H. (1986). A mathematical framework for studying learning in classifier systems. Physica 22D: 307–317.
Houle, D. (1991). Genetic covariance of fitness correlates: what genetic correlations are made of and why it matters. Evolution 45: 630–648.
Houston, A.I. and J.M. McNamara (1992). Phenotypic plasticity as a state-dependent life-history decision. Evolutionary Ecology 6: 243–253.
Kauffman, S.A. (1991). Antichaos and adaptation. Scientific American, August, pp. 78–84.
Kauffman, S.A. (1993). The Origins of Order. Oxford, Oxford University Press.
Kauffman, S.A. and S. Levin (1987). Towards a general theory of adaptive walks on rugged landscapes. J. Theor. Biol. 128: 11–45.
Kauffman, S.A. and R.G. Smith (1986). Adaptive automata based on Darwinian selection. Physica 22D: 68–82.
Kirkpatrick, M. and D. Lofsvold (1992). Measuring selection and constraint in the evolution of growth. Evolution 46: 954–971.
Lakatos, I. (1974). Falsification and the methodology of scientific research programmes. In: I. Lakatos and A. Musgrave, eds., Criticism and the Growth of Knowledge. Cambridge, Cambridge University Press.
Lande, R. (1979). Quantitative genetic analysis of multivariate evolution, applied to brain: body size allometry. Evolution 33: 402–416.
Lande, R. and S.J. Arnold (1983). The measurement of selection on correlated characters. Evolution 37: 1210–1226.
Langton, C.G. (1986). Studying artificial life with cellular automata. Physica 22D: 120–149.
Levins, R. and R.C. Lewontin (1985). The Dialectical Biologist. Cambridge, Harvard University Press.
Lewin, B. (1994). Genes. New York, Wiley & Sons.
Lewontin, R.C. (1974). The analysis of variance and the analysis of causes. American Journal of Human Genetics 26: 400–411.
Lewontin, R.C. (1978). Adaptation. Scientific American, October, pp. 213–230.
Lewontin, R.C. (1991). Biology as Ideology. New York, Harper.
Lorenz, E.N. (1963). Deterministic nonperiodic flow. Journal of Atmospheric Sciences 20: 130–141.
May, R.M. (1976). Simple mathematical models with very complicated dynamics. Nature 261: 459–467.
Maynard Smith, J. (1982). Evolution and the Theory of Games. Cambridge UK, Cambridge University Press.
Mayr, E. and W.B. Provine, eds. (1980). The Evolutionary Synthesis. Cambridge, MA, Harvard University Press.
Mandelbrot, B.B. (1992). Fractals and the rebirth of experimental mathematics. In: H. Peitgen, H. Jurgens and D. Saupe, eds., Fractals for the Classroom. New York, Springer-Verlag.
Mazer, S.J. and C.T. Schick (1991a). Constancy of population parameters for life-history and floral traits in Raphanus sativus. I. Norms of reaction and the nature of genotype by environment interactions. Heredity 67: 143–156.
Mazer, S.J. and C.T. Schick (1991b). Constancy of population parameters for life-history and floral traits in Raphanus sativus. II. Effects of planting density on phenotype and heritability estimates. Evolution 45: 1888–1907.
Moore, A.J. and C.R.B. Boake (1994). Optimality and evolutionary genetics: complementary procedures for evolutionary analysis in behavioral ecology. Trends in Ecology and Evolution 9: 69–72.
Nijhout, H.F. G.A. Wray, C. Kremen and C.K. Teragawa (1986). Ontogeny, phylogeny and evolution of form: an algorithmic approach. Systematic Zoology 35: 445–457.
Novak, J.D. and D. Gowin (1984). Learning How to Learn. New York, Cambridge University Press.
Oreskes, N., K. Shrader-Frechette and K. Belitz (1994). Verification, validation, and confirmation of numerical models in the Earth sciences. Science 263: 641–646.
Pigliucci, M. (1996). How organisms respond to environmental changes: from phenotype to molecules (and vice versa). Trends in Ecology & Evolution 11: 168–173.
Pigliucci, M., C.D. Schlichting, C. Jones, and K. Schwenk (1997). Developmental reaction norms: the interaction among allometry, ontogeny and plasticity. Plant Species Biology 11: 69–86.
Pines, D. (ed.) (1986). Emerging Synthesis in Science. Redwood City, CA, Addison-Wesley
Prigogine, I. (1980). From Being to Becoming. San Francisco, Freeman.
Provine, W.B. (1971). The Origins of Theoretical Population Genetics. Chicago, University of Chicago Press.
Ray, T.S. (1992). Evolution, ecology and optimization of digital organisms. Santa Fe Institute working paper 92–08–042.
Riska, B. (1989). Composite traits, selection response, and evolution. Evolution 43: 1172–1191.
Saunders, P.T. (1980). An Introduction to Catastrophe Theory. Cambridge UK, Cambridge University Press.
Scheiner, S.M. (1993). Genetics and evolution of phenotypic plasticity. Annual Review of Ecology and Systematics 24: 35–68.
Schlichting, C.D. (1986). The evolution of phenotypic plasticity in plants. Annual Review of Ecology and Systematics 17: 667–693.
Schlichting, C.D. and M. Pigliucci (1993). Control of phenotypic plasticity via regulatory genes. The American Naturalist 142: 366–370.
Schlichting, C.D. and M. Pigliucci (1995). Gene regulation, quantitative genetics, and the evolution of reaction norms. Evolutionary Ecology 9: 154–168.
Slatkin, M. (1987). Quantitative genetics of heterochrony. Evolution 41: 799–811.
Stearns, S.C. and J.C. Koella (1986). The evolution of phenotypic plasticity in life-history traits: predictions of reaction norms for age and size at maturity. Evolution 40: 893–913.
Stenseth, N.C. and J. Maynard Smith (1984). Coevolution in ecosystems: Red Queen evolution or stasis? Evolution 38: 870–880.
Sultan, S.E. (1987). Evolutionary implications of phenotypic plasticity in plants. Evolutionary Biology 21: 127–178.
Tachida, H. and C.C. Cockerham (1989). Effects of identity disequilibrium and linkage on quantitative variation in finite populations. Genetical Research 53: 63–70.
Thom, R. (1983). Mathematical Models of Morphogenesis. Chichester UK, Horwood Ltd.
Turchin, P. and A.D. Taylor (1992). Complex dynamics in ecological time series. Ecology 73: 289–305.
Turelli, M. (1988). Phenotypic evolution, constant covariances, and the maintenance of additive variance. Evolution 42: 1342–1347.
Turelli, M. and N.H. Barton (1990). Dynamics of polygenic characters under selection. Theoretical Population Biology 38: 1–57.
Turing, A. (1952). The chemical basis of morphogenesis. Philosophical Transactions of the Royal Society of London B 237: 37–72.
Tienderen, P.H. van (1991). Evolution of generalists and specialists in spatially heterogeneous environments. Evolution 45: 1317–1331.
Valen, L. van (1973). A new evolutionary law. Evolutionary Theory 1: 1–30.
Via, S. (1987). Genetic constraints on the evolution of phenotypic plasticity. In: V. Loeschcke, ed., Genetic Constraints on Adaptive Evolution. Berlin, Springer-Verlag.
Via, S. and R. Lande (1985). Genotype-environment interaction and the evolution of phenotypic plasticity. Evolution 39: 505–522.
Via, S. and R. Lande (1987). Evolution of genetic variability in a spatially heterogeneous environment: effects of genotype-environment interaction. Genetical Research 49: 147–156.
Neumann, J. von (1966). Theory of Self-Reproducing Automata. Urbana-Champaign, IL, University of Illinois Press.
Waddington, C.H. (1974). A catastrophe theory of evolution. Annals New York Academy of Sciences 231: 32–42.
Wallace, B. (1989). One selectionist's perspective. Quarterly Review of Biology 64: 127–145.
Wallace, B. (1991). Fifty Years of Genetic Load: an Odyssey. Ithaca, Cornell University Press.
West-Eberhard, M.J. (1989). Phenotypic plasticity and the origins of diversity. Annual Review of Ecology and Systematics 20: 249–278.
Wilkinson, G.S., K. Fowler and L. Partridge (1990). Resistance of genetic correlation structure to directional selection in Drosophila melanogaster. Evolution 44: 1990–2003.
Willis, J.H. and H.A. Orr (1993). Increased heritable variation following population bottlenecks: the role of dominance. Evolution 47: 949–956.
Wolfram, S. (1984). Cellular automata as models of complexity. Nature 311: 419–424.
Wright, S. (1931). Evolution in Mendelian populations. Genetics 16: 97–159.
Wright, S. (1980). Genic and organismic selection. Evolution 34: 825–843.
Young, S.S.Y. and H. Weiler (1960). Selection for two correlated traits by independent culling levels. Journal of Genetics 57: 329–338.
Zeeman, E.C. (1976) Duffing's equation in brain modelling. Bulletin of the Institute of Mathematics and its Applications. 12: 207–214.
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Pigliucci, M., Schlichting, C.D. On the Limits of Quantitative Genetics for the Study of Phenotypic Evolution. Acta Biotheor 45, 143–160 (1997). https://doi.org/10.1023/A:1000338223164
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DOI: https://doi.org/10.1023/A:1000338223164