264 CHAPTER 10
dandelion (see Figure 10.20C), which is very successful at colonizing new patches
of habitat, gain an advantage from parthenogenesis through reproductive assur-
ance: in the absence of other individuals, just a single unfertilized seed can start
a whole new population. Another advantage is that sexually transmitted diseases,
which are suffered by plants as well as animals, are avoided by organisms without
sex. Together with the twofold cost of producing males, these further factors would
seem to give parthenogenesis an overwhelming evolutionary advantage. Yet the
ubiquity of sexual reproduction shows that is not the case.
Since sexual reproduction is so overwhelmingly common in life on Earth, it must
have some benefits that offset these drawbacks. The most fundamental feature of
sex is that it causes genetic mixing: zygotes carry combinations of alleles inher-
ited from two parents (see Chapter 4). In most eukaryotes, the mixing results from
segregation and recombination that happen during meiosis, and then fusion of the
sperm and egg. Prokaryotes rely on various kinds of parasexuality we mentioned
earlier. The solution to the evolutionary enigma of sex must involve this mixing.
Advantages to sex in changing environments
Clues about the factors that favor sex can be gleaned from looking at species that
have both sexual and asexual reproduction. Sex seems to be more common in
those species in situations where the environment is changing. Water fleas (genus
Daphnia) are small crustaceans that live in freshwater lakes. During the summer,
the populations are entirely female and reproduce for several generations by par-
thenogenesis. In the fall, sexual males and females appear. They mate and pro-
duce eggs that lie dormant through the winter, then hatch to start the cycle again
in the spring. The chemistry and biology of a lake can change substantially from
one year to the next, and it seems that sexual reproduction is timed to happen
when the environment is most unpredictable.
The timing of sexual reproduction in water fleas suggests that changing envi-
ronments can favor sex but not why they do so. A popular argument (frequently
repeated in introductory biology texts) is that sex is favored because it increases
genetic variation. On closer inspection, there are problems with that idea. A useful
analogy here is with a card game in which the cards play the role of alleles [34]. Say
that you have just won a game with a very good hand. If you had the choice, would
you keep those cards for the next game, or would you mix half of the cards you
now have with random ones taken from the deck? If the rules of the game don't
Futuyma Kirkpatrick Evolution, 4e
Sinauer Associates
Troutt Visual Services
Evolution4e_10.21.ai Date 12-15-2016 01-25-17
Frequency of asexuals
2 4 6
Generation
8 10
0.4
0.2
0.6
0
1.0
(A) (B)
0.8
Sexual
Asexual
FIGURE 10.21 The biggest evolutionary
disadvantage of sexual reproduction is
the twofold cost of males. (A) Each female
produces two offspring. The sexual
females are exactly replacing themselves,
and their numbers are stable. Asexual
females produce only daughters, and so
their numbers double in each genera-
tion. (B) If all else is equal, a mutation in a
sexual population that causes females to
reproduce asexually will spread to fixation
in just a few generations. The fact that
asexuality is so rare shows that there must
be strong advantages to sexual repro-
duction that compensate for the twofold
cost of producing males.
10_EVOL4E_CH10.indd 264 3/22/17 2:25 PM