Hostname: page-component-7b9c58cd5d-v2ckm Total loading time: 0 Render date: 2025-03-15T23:46:07.288Z Has data issue: false hasContentIssue false
  • English
  • Français

Causal Processes, Fitness, and the Differential Persistence of Lineages

Published online by Cambridge University Press:  01 January 2022

Frédéric Bouchard
Get access Rights & Permissions [Opens in a new window]

Abstract

Ecological fitness has been suggested to provide a unifying definition of fitness. However, a metric for this notion of fitness was in most cases unavailable except by proxy with differential reproductive success. In this article, I show how differential persistence of lineages can be used as a way to assess ecological fitness. This view is inspired by a better understanding of the evolution of some clonal plants, colonial organisms, and ecosystems. Differential persistence shows the limitation of an ensemblist noncausal understanding of evolution. Causal explanations are necessary to understand the evolution by natural selection of these biological systems.

Type
The Role of Causal Explanations in Understanding Natural Selection
Information
Philosophy of Science , Volume 75 , Issue 5: Proceedings of the 2006 Biennial Meeting of the Philosophy of Science Association. Part II: Symposia Papers. Edited by Cristina Bicchieri and Jason Alexander , December 2008 , pp. 560 - 570
Copyright
Copyright © The Philosophy of Science Association

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Barbault, R., and Blandin, P. (1980), “La notion de stratégie adaptative: Sur quelques aspects énergétiques, démographiques et synécologiques”, in Barbault, R., Blandin, P., and Meyer, J. A. (eds.), Recherches d’écologie théorique: Les stratégies adaptatives. Paris: Maloine, 127.Google Scholar
Blandin, P. (1979), “Évolution des écosystèmes et stratégies cénotiques”, in Barbault, R., Blandin, P., and Meyer, J. A. (eds.), Recherches d’écologie théorique: Les stratégies adaptatives. Paris: Maloine, 221235.Google Scholar
Blandin, P., and Lamotte, M. (1989), “L’organisation hiérarchique des systèmes écologiques”, L’organisation hiérarchique des systèmes écologiques 7:3547.Google Scholar
Bouchard, Frédéric (2006), “Fitness”, in Pfeifer, J. and Sarkar, S. (eds.), The Philosophy of Science: An Encyclopedia. London: Routledge, 310315.Google Scholar
Bouchard, Frédéric, and Rosenberg, Alex (2004), “Fitness, Probability and the Principles of Natural Selection”, Fitness, Probability and the Principles of Natural Selection 55 (4): 693712..Google Scholar
Cook, Robert E. (1980), “Reproduction by Duplication”, Reproduction by Duplication 89 (3): 8893..Google Scholar
Endler, John A. (1986), Natural Selection in the Wild. Monographs in Population Biology. Princeton, NJ: Princeton University Press.Google Scholar
Gill, Douglas E., and Halverson, Timothy G. (1984), “Fitness Variation among Branches within Trees”, in Shorrocks, B. (ed.), Evolutionary Ecology: The 23rd Symposium of the British Ecological Society, Leeds, 1982. Oxford: Blackwell, 105116.Google Scholar
Gough, Laura, Goldberg, Deborah E., Hershock, Chad, Pauliukonis, Nijole, and Petru, Martina (2002), “Investigating the Community Consequences of Competition among Clonal Plants”, Investigating the Community Consequences of Competition among Clonal Plants 15:547563.Google Scholar
Grant, Michael C. (1993), “The Trembling Giant”, The Trembling Giant 14 (10): 8289..Google Scholar
Harper, J. L. (1978), “The Demography of Plants with Clonal Growth”, in Freysen, A. H. J. and Woldendorp, J. W. (eds.), Structure and Functioning of Plant Populations. Amsterdam: North-Holland, 2748.Google Scholar
Jackson, Jeremy B. C., Buss, Leo W., and Cook, Robert E., eds. (1985), Population Biology and Evolution of Clonal Organisms. New Haven, CT: Yale University Press.Google Scholar
Lewontin, Richard C. (1978), “Adaptation”, Adaptation 239 (3): 156169..Google ScholarPubMed
Mameli, Matteo (2004), “Nongenetic Selection and Nongenetic Inheritance”, Nongenetic Selection and Nongenetic Inheritance 55 (1): 3572..Google Scholar
Matthen, Mohan, and Ariew, André (2002), “Two Ways of Thinking about Fitness and Natural Selection”, Two Ways of Thinking about Fitness and Natural Selection 99 (2): 5583..Google Scholar
Mitton, Jeffrey B., and Grant, Michael C. (1996), “Genetic Variation and the Natural History of Quaking Aspen”, Genetic Variation and the Natural History of Quaking Aspen 46 (1): 2531..Google Scholar
Oborny, Beáta, and Kun, Ádám (2001), “Fragmentation of Clones: How Does It Influence Dispersal and Competitive Ability?”, Fragmentation of Clones: How Does It Influence Dispersal and Competitive Ability? 15:319346.Google Scholar
Odling-Smee, F., Laland, K. N., and Feldman, M. W. (2003), Niche Construction. Princeton, NJ: Princeton University Press.Google Scholar
Olejniczak, Pawel (2003), “Optimal Allocation to Vegetative and Sexual Reproduction in Plants: The Effect of Ramet Density”, Optimal Allocation to Vegetative and Sexual Reproduction in Plants: The Effect of Ramet Density 17:265275.Google Scholar
Rosenberg, Alex, and Bouchard, Frédéric (2005), “Matthen and Ariew's Obituary to Fitness: Reports of Its Death Have Been Greatly Exaggerated”, Matthen and Ariew's Obituary to Fitness: Reports of Its Death Have Been Greatly Exaggerated 20 (2–3): 343353.Google Scholar
Tamm, Anneli, Kull, Kalevi, and Sammul, Marek (2002), “Classifying Clonal Growth Forms Based on Vegetative Mobility and Ramet Longevity: A Whole Community Analysis”, Classifying Clonal Growth Forms Based on Vegetative Mobility and Ramet Longevity: A Whole Community Analysis 15:381401.Google Scholar
Tansley, A. G. (1935), “The Use and Abuse of Vegetational Concepts and Terms”, The Use and Abuse of Vegetational Concepts and Terms 16 (3): 284307..Google Scholar
Thoday, J. M. (1953), “Components of Fitness”, in Evolution. Symposia of the Society for Experimental Ecology, vol. 7. Cambridge: Cambridge University Press, 96113.Google Scholar
Turner, J. Scott (2000), The Extended Organism: The Physiology of Animal-Built Structures. Cambridge, MA: Harvard University Press.Google Scholar
Van Valen, Leigh M. (1989), “Three Paradigms of Evolution”, Three Paradigms of Evolution 9:117.Google Scholar
Walsh, Denis M., Ariew, André, and Lewens, Tim (2002), “The Trials of Life: Natural Selection and Random Drift”, The Trials of Life: Natural Selection and Random Drift 69:452473.Google Scholar
Wilson, Edward O. (1971), The Insect Societies. Cambridge, MA: Belknap.Google Scholar
Wilson, Edward O. (1974), “The Perfect Societies”, The Perfect Societies 184 (4132): 5455..Google Scholar