THE EvoluTion of GEnEs And GEnomEs 347
The Birth of a Gene
One of the most fundamental questions we can ask about evolution is: How does
biological novelty originate? The answer must lie partly with the origin of genes
that have new functions. Like much of evolutionary genetics, this research topic
has exploded recently with the arrival of large numbers of genome sequences from
diverse branches of the tree of life [12].
The human eye is a remarkable organ. It forms a high-resolution image by
focusing light through a transparent lens made of living tissue. The lens is made
up largely of proteins called crystallins. Where did they originate? It turns out that
many proteins happen to be largely transparent. Crystallins in the vertebrate lens
are derived from proteins with a variety of other functions, for example a small
heat-shock protein that protects many tissues from different types of stress [14].
Crystallins in other animals are derived from different proteins with yet other
functions (FIGURE 14.3). In some instances, crystallins continue to function in
their original roles while also serving in the lens [56].
The crystallins show how novel biochemical functions can originate by a pro-
cess central to Darwin’s theory: descent with modification. Some of them origi-
nated by gene duplication (see Chapter 4). Duplication is the most common way
that new genes arise in eukaryotes. At the molecular level, duplications are caused
by several mechanisms. One is unequal crossing over, in which recombination
happens between different positions on chromosomes that are misaligned during
meiosis. Another is replication slippage, in which the DNA polymerase loses its
place and copies a segment of chromosome twice. In either event, the resulting
chromosomes can carry a gene that is duplicated in tandem with the parental copy.
A third way that gene duplicates arise is by retrotransposition. Here the messenger
RNA from a gene is reverse-transcribed to DNA, which is then integrated into the
genome. The result is a duplicate gene that is far from the parental copy, often on
a different chromosome. Duplicates that originate this way can be distinguished
from their parental genes because they lack introns, which were spliced out of the
mRNA before it was reverse-transcribed.
Futuyma Kirkpatrick Evolution, 4e
Sinauer Associates
Troutt Visual Services
Evolution4e_14.03.ai Date 12-30-2016
α β
γ γ
Glyceraldehyde phosphate dehydogenase
Crystallin Ancestral protein function
α Small heat-shock proteins
β/γ Related to bacterial stress protein
δ Arginosuccinate lyase
ε Lactate dehydrogenase
τ α-Enolase
ρ NADPH-dependent reductase
λ Hydroxyacyl-CoA dehydrogenase
ζ Alcohol dehydrogenase
η Aldehyde dehydrogenase
μ Similar to bacterial ornithine deaminase
π
ζ
Guinea
pig
ρ
Frog
δ τ
Turtle
δ τ π
Lizard
δ ε
Crocodile
δ ε
Bird
λ
Rabbit
ζ
Camel
μ
Kangaroo
η
Human
FIGURE 14.3 Crystallin proteins in the
lens of vertebrate eyes allow them to
focus light. Different groups of vertebrates
have different crystallins derived from a
wide variety of proteins with other func-
tions. (After [64].)
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