Evolution, 4th Edition

(Amelia) #1
Futuyma Kirkpatrick Evolution, 4e
Sinauer Associates
Troutt Visual Services
Evolution4e_05.19.ai Date 12-13-2016

20 40 60 80 100

0.2

0.4

0.6

0.8

1.0

0
Generation

Frequency of

A
2

(A) Positive

w 11 w 12 w 22

Fitness

20 40 60 80 100

0.2

0.4

0.6

0.8

1.0

0
Generation

Frequency of

A
2

(B) Overdominance

w 11 w 12 w 22

Fitness

20 40 60 80 100

0.2

0.4

0.6

0.8

1.0

0
Generation

Frequency of

A
2

(C) Underdominance

w 11 w 12 w 22

Fitness

FIGURE 5.19 Allele frequency trajectories under
three kinds of selection. In each case, trajectories
are shown for three different starting frequencies
of the A 2 allele. (A) Positive selection favors allele
A 2 , which spreads to fixation from any starting
frequency. In this example, A 2 increases fitness by
s = 0.05, and the relative fitnesses are w 11 = 1,
w 12 = 1.05, and w 22 = 1.1. (B) With overdominance,
the A 1 A 2 heterozygote has highest fitness. Starting
at any allele frequency, A 2 evolves to a polymor-
phic equilibrium. Selection preserves genetic
variation. In this example, the relative fitnesses
are w 11 = 0.9, w 12 = 1, and w 22 = 0.8, and the final
frequency of allele A 2 is 0.33 (dashed line). (C) With
underdominance, the A 1 A 2 heterozygote has the
lowest fitness. Populations evolve to different final
allele frequencies depending on where they start.
In this example, the relative fitnesses are w 11 = 1.1,
w 12 = 1, and w 22 = 1.2. If allele A 2 starts at a fre-
quency below 0.33 (dashed line), it is lost, but if it
starts above that frequency it spreads to fixation.

to use the heterozygote as the fitness reference. Estimates for the relative survival
of the three genotypes in Nigeria (a country in equatorial West Africa) are:

Genotype AA AS SS
Relative survival 0.88 1 0.14
Although these data are now 40 years old, recent research shows that malaria con-
tinues to cause strong selection on the β-hemoglobin locus [14].
This is the most famous example of overdominance, which occurs when the
heterozygote has higher fitness than both homozygotes. (Another example comes
from the Soay sheep discussed earlier; see Figure 5.13.) Overdominance leads to
a kind of evolutionary outcome that we have not yet discussed. The population
evolves to a stable polymorphic equilibrium, which means that both alleles are
maintained. Given the relative fitnesses of the AA and SS homozygotes (and again
using the AS heterozygote as the fitness reference), a mathematical model like that
in Box 5A tells us that any population that has genetic variation will evolve to the
same final allele frequency (FIGURE 5.19). Ultimately the population reaches an
equilibrium at which the frequency of the S allele is

(5.7)

This formula holds for any values of wAA and wSS that lie between 0 and 1.

p

1 – wAA
ˆ=
2 – wAA – wSS

05_EVOL4E_CH05.indd 121 3/23/17 9:01 AM

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