280 CHAPTER 11patches before becoming extinct. This lifestyle favors the evolution of early repro-
duction, so many weeds have evolved to mature at a young age. Common ragweed
(Ambrosia artemisiifolia), an American plant that is invading Europe and produces
pollen that is a major cause of hay fever, colonizes road edges and other disturbed
soils. Its seeds germinate in late spring and it flowers in early fall, just 4–5 months
later. In contrast, some oak trees do not mature for several decades.
In a sexually reproducing population, we can also use a life table to find the
fitness of an allele. For the survivorship (lx) and fecundity (mx) entries, we use the
average values in males and females for individuals that carry the allele. Alleles
with larger values of R have higher fitness and will spread. (Again, a correction
is needed if R is much different than 1.) Suppose a mutation appears in a popula-
tion that has the life table we just looked at. The mutation increases the average
fecundity of both males and females at age 2 from 1 to 1.2 offspring. That increases
l 2 m 2 from 0.5 to 0.6, and so R increases from 1 to 1.1. The mutation has higher fit-
ness than the other allele at the same locus (which has R = 1). The mutation will
increase in frequency, causing the life history of the population to evolve and the
growth rate R to increase.Senescence
Our life table illustrates a general point: natural selection does not act to prolong survival
beyond the last age of reproduction. In the life table above, a mutation that increases
the chance of survival to age 4 from 0 to 0.25 has no effect on R, because females
do not reproduce at that age. (There are a small number of interesting exceptions.
In humans and orca whales, postreproductive parents care for their offspring, so
postreproductive survival may be advantageous [15, 19].) But why should reproduc-
tion cease? Why do women experience menopause, and older men have lowered
sperm production and sex drive? The answer is that, all else being equal, the selec-
tive advantage of reproducing declines with age.
Increasing survival and fecundity at earlier ages has a larger effect on fitness
than at later ages, simply because predators, disease, and all sorts of accidents
make individuals less likely to survive to the later ages. In the discussion of the life
table above, we saw that a mutation that increases fecundity at age 2 from 1 to 1.2
increases fitness, R, from 1 to 1.1. Now consider a second mutation that increases
fecundity by the same amount at age 3 instead of age 2, increasing l 3 m 3 from 0.5 to
0.55. Comparing the life tables for the two mutations, we have:First mutation Second mutationx lx mx lx mx lx mx lx mx
0
1
2
3
41
0.75
0.5
0.25
00
0
1.2
2
00
0
0.6
0.5
01
0.75
0.5
0.25
00
0
1
2.2
00
0
0.5
0.55
0.00
R: 1.1 R: 1.05We see that the second mutation increases R from 1 to 1.05. This is a smaller
increase in fitness than that for the first mutation, because a smaller number of
individuals survive to age 3 than to age 2.
The principle that increasing survival and fecundity at earlier ages has a larger
effect on fitness than at later ages is the basis of the two major factors respon-
sible for the evolution of senescence and life span. One, first identified by Peter
Medawar [36], is mutation accumulation: mutations that compromise biological11_EVOL4E_CH11.indd 280 3/22/17 1:11 PM