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Michod RE. Evolution of interactions in family-structured populations: mixed mating models. Genetics. 1980;96(1):275-96doi: 10.1093/genetics/96.1.275.
Michod, R. E. (1980). Evolution of interactions in family-structured populations: mixed mating models. Genetics, 96(1), 275-96. https://doi.org/10.1093/genetics/96.1.275
Michod, R E. "Evolution of interactions in family-structured populations: mixed mating models." Genetics vol. 96,1 (1980): 275-96. doi: https://doi.org/10.1093/genetics/96.1.275
Michod RE. Evolution of interactions in family-structured populations: mixed mating models. Genetics. 1980 Sep;96(1):275-96. doi: 10.1093/genetics/96.1.275. PMID: 17249062; PMCID: PMC1214295.
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Genetics. 1980 Sep;96(1):275-96. doi: 10.1093/genetics/96.1.275.

Evolution of interactions in family-structured populations: mixed mating models.

Genetics

R E Michod

Affiliations

  1. Department of Ecology and Evolutionary Biology, University of Arizona, Tucson, Arizona 85721.

PMID: 17249062 PMCID: PMC1214295 DOI: 10.1093/genetics/96.1.275

Abstract

THE EFFECT OF INBREEDING ON SOCIALITY IS STUDIED THEORETICALLY FOR THE EVOLUTION OF INTERACTIONS BETWEEN SIBLINGS IN CERTAIN MIXED MATING SYSTEMS THAT GIVE RISE TO INBREEDING: sib with random mating and selfing with random mating. Two approaches are taken. First, specific models of altruism are studied for the various mating systems. In the case of the additive model, inbreeding facilitates the evolution of altruistic genes. Likewise, for the multiplicative model this is usually the case, as long as the costs of altruism are not too great. Second, the case of total altruism, in which the gene has zero individual fitness but increases the fitness of associates, is studied for a general fitness formulation. In this case, inbreeding often retards the ability of such genes to increase when rare, and the equilibrium frequency of those recessive genes that can increase is totally independent of the mating system and, consequently, of the amount of inbreeding. It appears from the results presented that inbreeding facilitates most forms of altruism, but retards extreme altruism. These results stem from the fact that inbreeding increases the within-family relatedness by increasing the between-family variance in allele frequency. In most cases this facilitates altruism. However, in the case of total altruism, only heterozygotes can pass on the altruistic allele, and inbreeding tends to decrease this heterozygote class. In either case, the important effect of inbreeding lies in altering the genotypic distribution of the interactions.

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