Abstract
A framework is presented in which the role ofdevelopmental rules in phenotypic evolution canbe studied for some simple situations. Usingtwo different implicit models of development,characterized by different developmental mapsfrom genotypes to phenotypes, it is shown bysimulation that developmental rules and driftcan result in directional phenotypic evolutionwithout selection. For both models thesimulations show that the critical parameterthat drives the final phenotypic distributionis the cardinality of the set of genotypes thatmap to each phenotype. Details of thedevelopmental map do not matter. If phenotypesare randomly assigned to genotypes, the lastresult can also be proved analytically.
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Aggarwal, A., Ma, W., Sandri, G. vH. and Sarkar, S.: 1992. ‘Adaptive Graph Computations with a Connection Machine’, in V.K. Prasanna and L.H. Canter (eds), Proceedings of the Sixth International Parallel Processing Symposium, IEEE Computer Society Press, Washington, pp. 18–21.
Aggarwal, A. and Sarkar, S. 1992. ‘On the Evolution of Complex Genomes: Adaptive Graph Computations with a CM-2 Connection Machine’, in H. Berghel, E. Deaton, G. Hedrick, D. Roach and R. Wainwright (eds), Applied Computing: Technological Challenges of the 1990s, ACM Press, New York, pp. 798–807.
Arthur, W.: 2002, ‘The Emerging Conceptual Framework of Evolutionary Developmental Biology’, Nature 415, 757–763.
Gilbert, S.F., Opitz, J.M. and Raff, R.A.: 1996, ‘Resynthesizing Evolutionary and Developmental Biology’, Developmental Biology 173, 357–372.
Haldane, J.B.S.: 1932, The Causes of Evolution, Harper and Brothers, London.
Hall, B.K.: 1998, Evolutionary Developmental Biology (2nd edn.), Chapman and Hall, London.
Hall, B.K.: 2000, ‘Eco-Devo or Devo-Evo-Does It Matter?’, Evolution and Development 2, 177–178.
Kauffman, S. and Levin, S.: 1987, ‘Towards a General Theory of Adaptive Walks on Rugged Landscapes’, Journal of Theoretical Biology 128, 11–45.
Kimura, M.: 1983, The Neutral Theory of Molecular Evolution, Cambridge University Press, Cambridge.
Macken, C.A. and Perelson, A.S.: 1989, ‘Protein evolution on rugged landscapes’, Proceedings of the National Academy of Sciences (USA) 86, 6191–6195.
Sarkar, S.: 1990, ‘On Adaptation: A Reduction of the Kauffman-Levin Model to a Problem in Graph Theory and Its Consequences’, Biology and Philosophy 5, 127–148.
Sarkar, S.: 2003, ‘Evolutionary Theory in the 1920s: The Nature of the “Synthesis”’, Philosophy of Science.
Sarkar, S. and Fuller, T.: 2003, ‘Generalized Norms of Reaction for Ecological Developmental Biology’, Evolution and Development 5, 106–115.
Sarkar, S., Garson, J. and Wang, L.: in preparation, ‘Developmental Maps and the Directionality of Evolution’.
Sober, S.: 1984, The Nature of Selection, MIT Press, Cambridge, MA.
Stadler, B.M.R., Stadler, P.F., Wagner, G.P. and Fontana, W.: 2001, ‘The Topology of the Possible: Formal Spaces Underlying Patterns of Evolutionary Change’, Journal of Theoretical Biology 213, 241–274.
Wagner, G.P.: 2000, ‘What Is the Promise of Developmental Evolution? Part I: Why Is Developmental Biology Necessary to Explain Evolutionary Innovations?’, Journal of Experimental Zoology (Molecular Development and Evolution) 288, 95–98.
Weinberger, E.: 1988, ‘A More Rigorous Derivation of Some Properties of Uncorrelated Fitness Landscapes’, Journal of Theoretical Biology 134, 125–129.
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Garson, J., Wang, L. & Sarkar, S. How Development May Direct Evolution. Biology & Philosophy 18, 353–370 (2003). https://doi.org/10.1023/A:1023996321257
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DOI: https://doi.org/10.1023/A:1023996321257