170 CHAPTER 7College Station, Texas, and genotyped them at several loci [35]. FIGURE 7.4 shows
the data from one locus. Allele frequencies differ on the two sides of the street. The
street acts as a strong barrier to dispersal between the two blocks, and the allele
frequency differences between them almost certainly accumulated by drift.The genealogy of genes
For a modest cost, you and your parents can have your genomes analyzed. With
those data, you can determine which gene copy at a locus you inherited from your
mother and which from your father. With the genomes of your ancestors going
back further in time, you could trace the evolutionary history of every gene in your
genome. Now imagine we did that for every person now alive. The result would
reveal a remarkable fact: for any given locus in the human genome, there was a
copy of that gene at some time in the past that was the ancestor of all copies of the
gene now carried by all living humans.
To make these ideas more clear, consider a second simulation experiment
(FIGURE 7.5). Here we follow the genealogy of the 10 gene copies at a locus in a
population of 5 individuals. The gene copies may or may not have the same DNA
sequence, but we again ensure there is no selection—all individuals have equal
chances of surviving and reproducing. In the first generation of the simulation,
some gene copies are lost when the individuals carrying them die by random
events, while others are lost when by chance they fail to be passed to a gamete
during meiosis. Looking at Figure 7.5B, we see that only six of the ten copies of the
gene present in generation 0 left descendants to generation 1. By chance alone, four
gene copies present in generation 0 will never be represented in future generations.
When generation 2 is produced by generation 1, accidents of survival and repro-
duction eliminate one more of the original 10 lineages (see Figure 7.5C). Once a
lineage goes extinct, it can never come back from the dead, so the total number of
lineages descending from the original population can only decrease in time.
By the time we reach generation 7, all of the gene copies are the descendants
of just one copy that was present in generation 0 (see Figure 7.5D). Looking from
generation 7 backward in time, we can trace the ancestry of all the gene copies.
That genealogy, shown by the red lines, is called the gene tree.
What happens if we run the simulation again? Genetic drift is random, and so
different copies of the gene will become the lucky winners that become ancestors
of all the future copies. Furthermore, the number of generations that it takes for Futuyma Kirkpatrick Evolution, 4e
Sinauer Associates
Troutt Visual Services
Evolution4e_07.04.ai Date 11-14-2016 01-18-17Cornu aspersum0 2010
MetersFIGURE 7.4 Allele frequency differences 10050
among populations of the garden snail
Cornu aspersum. The pie diagrams show the
frequencies of two alleles at the GOT-1 locus
in groups of snails found on two city blocks.
The sizes of the circles are proportional to
the numbers of individuals in each group.
The “50” allele (shown in blue) is quite
common in the left block but almost absent
from the right block. That difference almost
certainly evolved by drift. (After [35].)07_EVOL4E_CH07.indd 170 3/23/17 9:09 AM