gENETIC dRIfT: EvolUTIoN AT RANdoM 167
- Each generation starts with N juveniles. This population size is fixed by the
limited space that is available. - Every individual survives to become an adult, so there is no selection on survival.
- When adults reproduce, each individual makes 1000 sperm and 1000 eggs.
(The actual number does not matter so long as it is reasonably large.) Because
each individual makes the same number of gametes, there is no selection on
reproductive success. After reproduction, the adults die. - Zygotes are formed by random fertilization between sperm and eggs in the
pool of 2000N gametes. But since space is limited, only N randomly chosen
zygotes survive to become juveniles. The life cycle then begins again, and the
simulation returns to step 1.
What happens when we run the simulation? FIGURE 7.2 shows how allele fre-
quencies change over 500 generations in replicate populations that begin with an
allele frequency of p = 0.5. Frequencies fluctuate randomly. In each generation,
allele frequencies change by the random sampling of the genes that start the next
generation (step 4 of the simulation). This is the essence of genetic drift.Futuyma Kirkpatrick Evolution, 4e
Sinauer Associates
Troutt Visual Services
Evolution4e_07.02.ai Date 11-14-2016 01-18-1700.20.40.60.81100 200 300 400 500N = 500,00000.20.40.60.81100 200 300 400 500N = 50,00000.20.40.60.81100 200 300 400 500N = 500000.20.40.60.81100 200 300 400 500N = 500Allele frequency,p00.20.40.60.81100 200 300 400 500N = 5000.20.40.60.81100 200
Generation300 400 500N = 5FIGURE 7.2 Computer simulations of drift.
In each graph, five identical populations
start with two alleles at equal frequencies
(p = 0.5). Allele frequencies change in later
generations by random genetic drift (no
selection is acting). Smaller population sizes
cause bigger random changes in allele
frequencies in each generation, and lead
to quicker fixation (p = 0 or p = 1) of one
allele or the other.07_EVOL4E_CH07.indd 167 3/23/17 9:09 AM