From Natural Selection to Design: A Proposal of Extension of Formal Darwinism

Authors

  • Giorgio Airoldi Departamento de Lógica, Historia y Filosofía de la Ciencia, UNED
  • Cristian Saborido Departamento de Lógica, Historia y Filosofía de la Ciencia, UNED

DOI:

https://doi.org/10.48160/18532330me8.163

Keywords:

natural selection, complexity, fitness, robustness, formal models

Abstract

Darwin’s claim that Natural Selection, through optimization of fitness, explains complex biological design has not yet been properly formalized. Alan Grafen’s Formal Darwinism Project aims at providing such a formalization and at demonstrating that fitness maximization is coherent with results from Population Genetics, usually interpreted as denying it. We suggest that Grafen’s proposal suffers from some limitations linked to its concept of design as optimized fitness. In order to overcome these limitations, we propose a classification of evolutionary facts based on a bi-dimensional complexity space, which adds robustness to fitness as measure of the quality of a design. In this space, each point representsan organismic architecture, and movement between two points would be an evolutionary fact. Natural Selection explains movement along the fitness axis, while non-selective mechanisms explain movement on the robustness axis. Moreover, we propose a thermodynamic metaphor to draw parallelisms between notions of fitness and entropy, robustness and energy, and movement in this space and reversible and irreversible cycles. We argue that this metaphor illustrates different evolutionary processes usually overlooked by proposals of formalization of Darwinian theory, such Grafen’s Formal Darwinism Project.

References

Alberch, P. (1991), “From Genes to Phenotypes: Dynamical Systems and Evolvability”, Genetica84:5-11.

Bergman, B., De Maré, J., Svensson, T. y S. Loren (2009), Robust Design Methodology for Reliability: Exploring the Effects of Variation and Uncertainty, London: Wiley.

Darwin, C. (1983), El Origen de las Especies, Madrid: EDAF.

Carlson, J.M. y J. Doyle (2002), “Complexity and Robustness”, Proceedings of the National Academy of Sciences99: 2538-2545.

Charnov, E.L. (1976), “Optimal Foraging, the Marginal Value Theorem”, Theoretical Population Biology9(2): 129-136.

Clausing, D.P. (2004), “Operating Window: An Engineering Measure for Robustness”, Technometrics46 (1): 25-29.

Eldredge, N. y S.J. Gould (1972),“Punctuated Equilibria: An Alternative to Phyletic Gradualism”, en Schopf, T.J.M. (ed.), Models in Paleobiology, San Francisco: Freeman, Cooper and Company, pp.82-115.

Fisher, R.A. (1930), Genetical Theory of Natural Selection, Oxford: Oxford Clarendon Press.

Glansdorff, P. eI. Prigogine (1971), Thermodynamics of Structure, Stability and Fluctuations, London: Wiley.

Grafen, A. (1999), “Formal Darwinism, the Individual-As-Maximizing-Agent and Bet-Edging”, Proceedingsof the Royal Society of LondonB266: 799-803.

Grafen, A. (2007), “The Formal Darwinism project: AMid-Term Report”, Journalof Evolutionary Biology20: 1243-1254.

Grafen, A. (2014), “The Formal Darwinism Project in Outline”, Biology &Philosophy29: 155-174.

Gould, J.S. y E.S. Vrba (1982),“Exaptation-A Missing Term in the Science of Form”, Paleobiology8(1): 4-15.

Kauffman, S. (2000), Investigations, New York: Oxford University Press.

Kitano, H. (2004), “Biological Robustness”, Nature Reviews Genetics5(11): 826-837.

Kitano, H. (2007), “Towards aTheory of Biological Robustness”, Molecular Systems Biology3(1): 137.

Lewontin, R.C. (1974), The Genetic Basis of Evolutionary Changes, New York: Columbia University Press.

Maturana, H. y F.J. Varela (1980), Autopoiesis and Cognition: The Realization of the Living, Dordrecht: Reidel.

Mitchell, M. (2009), Complexity. A Guided Tour,New York: Oxford University Press.

Mossio, M., Bich, L. y A.Moreno (2013), “Emergence, Closure and Inter-Level Causation in Biological Systems”, Erkenntnis78:153-178.

Moczek, A.P. (2008), “On the Origins of Novelty in Development and Evolution”, BioEssays30: 432-447.

Parker, G. y J. Maynard Smith (1990), “Optimality Theory in Evolutionary Biology”, Nature348: 27-33.

Pigliucci, M. (2008), “Is Evolvability Evolvable?”, Nature Reviews Genetics9(1): 75-82.

Price, G.R. (1972),“Fisher's ‘Fundamental Theorem’Made Clear”, Annals of Human Genetics36(2): 129-140.

Saborido, C., Moreno, Ã.J. y M. Mossio (2010), “La dimensión teleológica del concepto de función biológica desde la perspectiva organizacional”, Teorema29(3): 31-56.

Wagner, A. (2011), The Origins of Evolutionary Innovations, New York: Oxford University Press.

Wagner, A. (2015), Arrival of the Fittest, London: Oneworld Publications.

Wright, S. (1982), “The Shifting Balance Theory and Macroevolution”, Annual Review of Genetics16: 1-19.

Published

2017-10-01

How to Cite

Airoldi, G., & Saborido, C. (2017). From Natural Selection to Design: A Proposal of Extension of Formal Darwinism. Metatheoria – Journal of Philosophy and History of Science, 8(1), 71–80. https://doi.org/10.48160/18532330me8.163