Abstract
Advances in multiagent simulation techniques make it possible to study more realistic dynamics of complex systems and allow evolutionary theories to be tested. Here I use simulations to assess the relative importance of reproductive systems (haplodiploidy vs. diploidy), mate selection (assortative mating vs. random mating) and social economics (pay-off matrices of evolutionary games) in the evolutionary dynamics leading to the emergence of social cooperation in the provision of parental care. The simulations confirm that haplo-diploid organisms and organisms mating assortatively have a higher probability for fixing alleles and require less favorable conditions for their fixation, than diploids or organisms mating randomly. The simulations showed that social behavior was most likely to emerge a) when the cost for parental investment was much lower than the benefits to the offspring, b) when cooperation improved synergistically the fitness of offspring compared to the corresponding egoistic behavior and c) when alleles coding for altruistic or social behavior could be rapidly fixed in the population, thanks to mechanisms such as haplo-diploidy and/or assortative mating. Cooperative social behavior always appeared if sociality conferred much higher fitness gains compared to non cooperative alternatives suggesting that the most important factors for the emergence and maintenance of social behavior are those based on energetic or efficiency considerations. The simulations, in congruence with the scant experimental evidence available, suggest that economic considerations rather than genetic ones are critical in explaining the emergence and maintenance of sociality.
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REFERENCES
Alexander, R.D. (1974). The evolution of social behavior. Annual Review of Ecology Systematics 5: 325-383
Bull, J.J. (1983). Evolution of sex determining mechanisms. Benjamin/Cummings, N.Y.
Buss, D. (1989). Sex differences in human mate preferences: Evolutionary hypotheses tested in 37 cultures. Behavioral and Brain Sciences 12: 1-49.
Cabrera, S. and K. Jaffe (1998). On the energetic cost of human societies: energy consumption as an econometric index. Interciencia 23: 350-354.
Caprio, M.A. and M.A. Hay (1995). Premating isolation in a simulation model generates frequency dependent selection and alters establishment rates of resistant natural enemies. Journal of Economic Entomology 88: 205-212.
Caswell, H. and D.E. Weeks (1986). Two-sex models: chaos, extinction and other dynamic consequences of sex. American Naturalist 128: 707-735.
Crespi, B.J. and J.C. Choe (eds) (1997). The Evolution of Social Behavior in Insects and Arachnids. Cambridge University Press, Cambridge, UK. 541 pp.
Cressman, R. (1988). Complex dynamical behavior of frequency-dependent viability selection: An example. Journal of Theoretical Biology 130: 167-173.
Davis, C.H. (1995). The effect of assortative mating and environmental variation on selection for sexual reproduction. Evolutionary Theory 11: 51-53.
Dieckmann, U. and M. Doebeli (1999). On the origin of species by sympatric speciation. Nature 400: 354-357.
Fonk, C. and K. Jaffe (1996). On the energetic cost of sociality. Physiology and Behavior 59: 713-719.
Gadagkar, R. (1990). Evolution of eusociality: the advantage of assured fitness returns. Philosophical Transactions Royal Society London B 329: 17-25.
Gadagkar, R. (1991). On testing the role of genetic asymmetries created by haplodiploidy in the evolution of eusociality in the Hymenoptera. Journal of Genetics 70: 1-31.
Goldberg, D.E. (1989). Genetic Algorithms in Search, Optimization and Machine Learning. Addison-Wesley Publishing Company Inc., N.Y.
Gouldringer, I., P. Brabant and A. Gallais (1996). Theoretical comparison of recurrent selection methods for the improvement of self-pollinated crops. Crop Science 36: 1171-1180.
Hamilton, W.D. (1964). The genetic evolution of social behaviour I and II. Journal of Theoretical Biology 7: 1-16 and 17–52.
Jaffe, K. (1995). Biodynamica, a simulation model of biological evolution (for a windows environment). http://www.labb.usb.ve/klaus.htm
Jaffe, K. (1996). On the dynamics of the evolution of sex or why the sexes are, in fact, always two? Interciencia 21: 259-267 and 22:48.
Jaffe, K. (1998). Sex, mate selection and evolution. In: Porto, V.W., N. Saravanan, D. Waagen and A.E. Eiben (Eds.). Lecture Notes in Computer Science 1447: Evolutionary Programming VII. Springer Verlag, Berlin. pp. 483-492.
Jaffe, K. (1999). On the adaptive value of some mate selection strategies. Acta Biotheoretica 47: 29-40.
Jaffe, K. (2000). Emergence and maintenance of sex among diploid organisms aided by assortative mating. Acta Biotheoretica 48(2): 137-147.
Jaffe, K. and C. Fonk (1994). Energetics of social phenomena: Physics applied to evolutionary biology. Il Nuovo Cimiento D 16(6): 543-553.
Jaffe, K. and G. Chacon (1995). Assortative mating: sex differences in mate selection for married and unmarried couples. Human Biology 67: 111-120.
Jaffe, K., S. Issa, E. Daniels and D. Haile (1997). Dynamics of the emergence of genetic resistance to pesticides among asexual and sexual organisms. Journal of Theoretical Biology 188: 289-299.
Jimenez-A., W. (1998). The role of kin selection theory on the explanation of biological altruism: A critical review. Journal of Comparative Biology 3: 1-14.
Kondrashov, A.S. and F.A. Kondrashov (1999). Interactions among quantitative traits in the course of sympatric speciation. Nature 400: 351-354.
LeClerc, J.E., B. Li, W.L. Payne and T.A. Cebula (1996). High mutation frequencies among Echerichia coli and Salmonella pathogens. Science 274: 1208-1211.
Levin, S.A., B. Grenfell, A. Hastings and A.S. Perelson (1997). Mathematical and computational challenges in population biology and ecosystem science. Science 275: 334-343.
Mable, B. K. and S.P. Otto (1998). The evolution of life cycles with haploid and diploid phases. Bioessays 20: 453-462.
Maynard-Smith, J. (1976). Evolution and the theory of games. American Scientist 64: 41-45.
Michener, C.D. (1974). The social behavior of the bees. Belknap Press, Harvard University, Cambridge, Massachusetts. 404 pp.
Miller, G.F. and P.M. Todd. 1994. Evolutionary wanderlust: Sexual selection with directional mate preferences. In: D. Cliff, P. Husbands, J.A. Meyer and S. Wilson eds. Proc. Third Inter. Conf. Simulation Adaptive Behav. (SAB-94), M.I.T. Press, Bradford Books, N.Y. pp 21-30.
Muradian, R., S. Issa and K. Jaffe (1999). Energy consumption of termite colonies of Nasutitermes ephratae. Physiology and Behavior 66: 731-735.
Ochoa, G. and K. Jaffe (1999). On sex, mate selection and the Red Queen. Journal of Theoretical Biology 199: 1-9.
Osborn, F. and K. Jaffe (1997). Cooperation vs. exploitation: interactions between Lycaenid (Lepidopera: Lycaenidae) larvae and ants. Journal of Research on the Lepidoptera 34: 69-82.
Queller, D.C. (1994). Extended parental care and the origin of eusociality. Proceedings of the Royal Society London B 256: 105-111.
Queller, D.C., J.E. Strassmann and C.R. Hughes (1988). Genetic relatedness in colonics of tropical wasps with multiple queens. Science 242: 1155-1157.
Reeve, H.K. (1993). Haplodiploidy, eusociality and absence of male parental and alloparental care in Hymenoptera: a unifying genetic hypothesis distinct from kin selection theory. Philosophical Transactions Royal Society London B 342: 335-352.
Roff, D.A. (1992). The Evolution of Life Histories. Chapman & Hall, N.Y. 535 pp.
Ruelle, D. (1991). Chance and Chaos. Princeton University Press, Princeton, 195 pp.
Simon, H.A. (1990). A mechanism for social selection and successful altruism. Science 250: 1665-1669.
West-Eberhard, M.J. (1975). The evolution of social behavior by kin selection. Quarterly Review Biology 50: 1-33.
Wilson, E.O. (1976). Sociobiology: A New Synthesis, Harvard University Press, Cambridge, Massachusetts.
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Jaffe, K. On the Relative Importance of Haplo-Diploidy, Assortative Mating and Social Synergy on the Evolutionary Emergence of Social Behavior. Acta Biotheor 49, 29–42 (2001). https://doi.org/10.1023/A:1010229506863
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DOI: https://doi.org/10.1023/A:1010229506863