128 CHAPTER 5an adaptive valley. If the allele frequency starts to the left of the low point, selection
drives the allele frequency toward 0. However, if the allele frequency starts to the
right of the valley, it evolves uphill toward 1. This visualization of how selection
causes gene frequencies to evolve is one of the most famous images in evolutionary
biology.
The fundamental theorem and the adaptive landscape make assumptions
that do not apply exactly to any natural populations. In many cases, though, they
give very good approximations that are useful to guide our thinking about evo-
lution. In other cases, the assumptions are violated in ways that make evolution
behave very differently. A particularly important situation where the fundamen-
tal theorem and adaptive landscape do not apply is when selection is frequency
dependent. In some cases, this can cause the mean fitness of a population to
decline [45].
FIGURE 5.26 shows a cartoon of an example. In a population of a bush, each
individual makes many fruits. One day, a mutation appears that makes individu-
als grow a trunk. Their neighbors are shaded out and die, which gives individuals
with the mutation more water and nutrients from the soil. The mutation therefore
spreads. But this fitness advantage comes at a cost: energy diverted into growing a
trunk causes individuals with the mutation to produce fewer fruits than did their
ancestors without the mutation. (Just imagine how much more fecund an oak tree
could be if all the energy devoted to growing its enormous truck were convertedFutuyma Kirkpatrick Evolution, 4e
Sinauer Associates
Troutt Visual Services
Evolution4e_05.25.ai Date 12-28-20160.2A 1 A 1 A 1 A 2 A 2 A 20.4 0.6 0.8 10.20.40.60.81.001.001.001.00.5 0.5 0.500.2 0.4 0.6 0.8 10.20.40.60.81.00
Frequency of A 20.2 0.4 0.6 0.8 10.20.40.60.81.00Mean tness,wRelative tness,wA 1 A 1 A 1 A 2 A 2 A 2 A 1 A 1 A 1 A 2 A 2 A 2(A) Positive (B) Overdominance (C) UnderdominanceFIGURE 5.25 Wright’s adaptive landscape under positive,
overdominant, and underdominant selection. For each case, the
fitnesses of the three genotypes are shown at the top, and the
adaptive landscape that results from them at the bottom. The
landscapes are the population’s mean fitness, w—, plotted against
the frequency of allele A 2. From a given starting point, the allele
frequency evolves in the direction that increases w—. The ar-
rows show the direction of allele frequency change. The vertical
dashed lines correspond to peaks and valleys on the landscapes.
(A) Positive selection in which allele A 2 is favored. The allele
spreads until it is fixed, which corresponds to the frequency atwhich mean fitness is maximized (the solid circle). (B) With over-
dominance (heterozygote advantage), the population evolves to
a stable polymorphic equilibrium, in this case with A 2 at a fre-
quency of 0.66. The mean fitness, w—, is again maximized at this fre-
quency (the solid circle). (C) With underdominance (heterozygote
disadvantage), if the frequency of A 2 starts below a threshold (here
at 0.33), its frequency declines until it is lost. If it starts above the
threshold, the frequency of A 2 increases until it becomes fixed. The
threshold represents an unstable equilibrium that minimizes mean
fitness, w— (the open circle). The loss of A 2 and fixation of A 2 corre-
spond to two local peaks on the adaptive landscape (solid circles).05_EVOL4E_CH05.indd 128 3/23/17 9:01 AM