After reading with interest the recent paper by Axenovich et al. (Heredity 98:99-105) and the commentary on it by R F Nespolo (Heredity 98:63-64), Philip Hedrick has written this short commentary on their findings that puts their conclusions in a familiar context for the readers of Heredity.
Paper by Axenovich et al https://www.nature.com/hdy/journal/v98/n2/abs/6800908a.html
News and Commentary by R F Nespolo https://www.nature.com/hdy/journal/v98/n2/full/6800925a.html
Cycling selection for litter size in arctic foxes
PW Hedrick
Various evolutionary scenarios have been suggested to explain the regular numerical cycles in some microtine rodents (Nespolo, 2007). The numbers of arctic foxes in inland populations also have approximately four-year cycles in response to the cycles in numbers of small rodents, mainly voles and lemmings. Using a detailed pedigree of captive animals, Axenovich et al. (2007) concluded that the variation in arctic fox number was mainly the result of variation in litter size determined primarily by polymorphism at a major gene. To explain the maintenance of this polymorphism, they presented a model in which the recessive genotype had the highest litter size in bad years and the lowest litter size in good years (Table 1a). In their model, “In years with low food supply, the survival rate of the small litters produced by A2A2 mothers was assumed to be k-times higher than that of large litters produced by A1A1 and A1A2 mothers.”
These litter sizes can be given as standardized relative fitnesses as in Table 1b. The conditions for genetic polymorphism for this model was first given by Haldane and Jayakar (1963) in which they showed that a polymorphism was maintained when the arithmetic mean fitness of genotype A2A2 over generations is greater than 1 and the geometric mean fitness of A2A2 is less than 1. To meet these conditions, assuming that there are three bad years to every good year (Axenovich et al. 2007), then 1.666 < k < 1.718, a range of 0.052, which encompasses the k = 1.7 value given as a stable polymorphism example by Axenovich et al. (2007). Or for a stable polymorphism with standardized fitness, 1.111 < k' < 1.145, a range of only about 3%. In other words, the conditions for polymorphism maintenance with dominance and cyclic fitness variation are quite restrictive (Hedrick et al. 1976).
Further, Axenovich et al. (2007) concluded that the “male effect was negligible” at this gene, indicating that selection is only occurring in females and not in males. Female-only selection can be modeled using the standardized fitnesses given in Table 1c. In this case, the conditions for a stable polymorphism, 1.056 < k'' < 1.063, are even more restrictive, encompassing a range of less than 0.7%. In other words, it appears unlikely that litter sizes and subsequent survival of the pups are so finely balanced that they meet these very limited conditions for a balanced polymorphism under cycling selection. It is possible that other types of balancing selection with broader conditions for stable polymorphism, such differential selection at different locations or genotype-specific habitat selection (Hedrick et al., 1986; Hedrick, 2006), or some kind frequency-dependent selection, may also be acting so that the conditions for stability are less restrictive. Or, as suggested by Axenovich et al. (2007), the farmed foxes analyzed for litter size may have inherited the allele for small litter size from coastal populations which have small litters and reproduce every year and the allele for large litter size from inland populations which large litters sizes but do not reproduce every year. If this putative litter size gene can be located and the different alleles characterized molecularly, perhaps the type of balancing selection, or other explanation, can be identified. These concerns do not detract from the fascinating statistical conclusion of Axenovich et al. (2007) that the best genetic model to explain the observed bimodal litter size in arctic foxes is one with a single major gene.
PW Hedrick is at the School of Life Sciences, Arizona State University, Tempe, Arizona 85287-4501, USA.
e-mail: philip.hedrick@asu.edu
Axenovich TI, Zorkoltseva IV, Akberdin IR, Beketov SV, Kashtanov SN, Zakharov IA, Borodin PM (2007). Inheritance of litter size at birth in farmed arctic foxes (Alopex lagopus, Canidae, Carnivora). Heredity 98: 99-105.
Haldane JBS, Jayakar SD (1963). Polymorphism due to selection of varying direction. J. Genet. 58: 237-242.
Hedrick PW (1986). Genetic polymorphism in heterogeneous environments: A decade later. Ann. Rev. Ecol. Syst. 17: 535-566.
Hedrick PW (2006). Genetic polymorphism in heterogeneous environments: The age of genomics. Ann. Rev. Ecol. Evol. Syst. 37: 67-93.
Hedrick PW, Ginevan ME, Ewing EP (1976). Genetic polymorphism in heterogeneous environments. Ann. Rev. Ecol. Syst. 7: 1-32.
Nespolo RF (2007). A complex population dynamic explained by a single-locus Mendelian model for litter size. Heredity 98: 63-64.
Paper by Axenovich et al https://www.nature.com/hdy/journal/v98/n2/abs/6800908a.html
News and Commentary by R F Nespolo https://www.nature.com/hdy/journal/v98/n2/full/6800925a.html
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