Abstract
We are adopting Brooks and Wiley's view of evolution as an irreversible process capable of producing increasingly greater complexity at higher organizational levels. We start from the assumption that the evolutionary force is intrinsic in the living system, and is in reality a continuous senescence function leading gradually and unavoidably to death. We are therefore seeking a senescence function that favors social rather than solitary agents in terms of longevity, without prespecifying in detail the agent's life span. We show that a senescence function relyling on negative (destructive) feedback links from metabolism to genetic program conforms with these specifications. We also show that senescence should affect all the regulation parameters of the agent, and that the system remains nonmanipulable and unpredictable as far as its life span is concerned. This senescence function favors the more “cognitive” agent models (the ones having additional regulation loops), and thus the emergence of organizations of a higher order that have more elaborate social relations.
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Langton CG (1988) Artificial life. In: Langton CG (ed) Artificial Life. Proceedings of an Interdisciplinary Workshop on the Synthesis and Simulation of Living Systems. Addison-Wesley, Redwood City
Brooks DR, Wiley EO (1988) Evolution as entropy: Toward a unified theory of biology, 2nd edn. University of Chicago Press, Chicago
Stewart J (1994) Un système cognitif sans neurones: les capacités d'adaptation d'apprentissage et de mémoire du système immunitaire. Intellectica 1 (18):15–43
Jacob F (1981) Le jeu des possibles. Essai sur la diversité du vivant. Éditions Fayard, Paris
Kanungo MS (1994) Genes and aging. Cambridge University Press, Cambridge
Dyson F (1985) Origins of Life. Cambridge University Press, Cambridge
Warner HR, Butler RN, Sprott RL, et al., (eds) (1987) Modern biological theories of aging. Raven Press, New York (Aging series, vol 31)
Rusting RL (1992) Why do we age? Sci Am, December, pp. 86–95
Zs.-Nagy I (1994) The membrane hypothesis of aging. CRC Press, London
Kirkwood TBL, Holliday R (1979) The evolution of ageing and longevity. Proc R S London, Ser B, Biol Sci 205: 531–546
Rosen R (1992) Cells and senescence. In: Bittar EE (ed) Developmental biology. JAI Press, Greenwich, pp. 191–203
Arking R (1998) Biology of aging. Sinauer, Sunderland
Hamilton WD (1966) The moulding of senescence by natural selection. J Theor Biol 12:12–45
Tzafestas ES (1996) Aging agents. LAFORIA Research Report 96/01
Tzafestas ES (1995) Compromising algorithmicity and plasticity in autonomous agent control systems: the autonomous cell. J Intell Syst in press (earlier version appeared as LAFORIA Research Report 95/33, December)
Tzafestas ES (1995) Vers une systémique des agents autonomes: des cellules, des motivations et des perturbations. Thèse de Doctorat de l'Université Pierre et Marie Curie, Paris
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Tzafestas, E.S. Aging agents. Artif Life Robotics 5, 46–57 (2001). https://doi.org/10.1007/BF02481320
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DOI: https://doi.org/10.1007/BF02481320