T HE EvoluTion of GEnEs And GEnomEs 349
of the enzymes that digests the bacteria is encoded by the RNASE1B locus, which
originated by gene duplication about 4 Mya. This new enzyme rapidly evolved
nine amino acid changes (FIGURE 14.6) [67]. Those changes allow the enzyme to
work in the low-pH environment of the monkey’s gut that is needed to ferment the
leaves.
Some proteins have repeated domains that confer part of their function. The
sodium channel that is critical to the firing of vertebrate nerves has four domains
with very similar structure (FIGURE 14.7). They arose by two rounds of duplication
of a gene in a remote ancestor that coded for only a single domain [34].
Mixtures of exons duplicated from genes with different functions can generate
new genes with new functions, a process that is called exon shuffling. Exon duplica-
tion and exon shuffling have played roles in the evolution of many eukaryotic genes
[42]. An example is the jingwei locus, which is found only in the fruit flies Drosophila
teissieri and D. yakuba (FIGURE 14.8). The first three exons of this gene are duplicates
of exons in the yellow-emperor (Ymp) gene found in many Drosophila species. The
fourth exon, however, is a duplicate of the entire alcohol dehydrogenase (Adh) gene
that was retrotransposed into an intron of Ymp. The new jingwei gene shows evi-
dence of rapid evolution by positive selection after it originated about 2 Mya.Futuyma Kirkpatrick Evolution, 4e
Sinauer Associates
Troutt Visual Services
Evolution4e_14.06.ai Date 01-02-2017Note: Could use photo from CH06 opener of 3e. Image here
is an FPO from David with the note
“Here's one you can put in with an FPO. If all we need is an inset
photo of a Douc langur here, I should probably look for a less expensive one”Nonsynonymous change
Synonymous changeHuman RNASE1Rhesus monkey RNASE1Douc langur RNASE1Douc langur
RNASE1BDuplication
dN/dS = 4.03FIGURE 14.6 Duplication and adaptation of the RNASE1 gene
in the douc langur. The gene tree relates the RNASE1B duplicate
locus in the douc langur to the RNASE1 locus in the langur, rhesus
monkey, and human. Branch lengths are proportional to the
number of substitutions in the coding region. Since the duplica-
tion event, there have been 12 changes to the coding region of
the duplicate, and none to the original copy of the gene. Of the
changes in the duplicate, nine are nonsynonymous and three are
synonymous. The dN/dS ratio (see Chapter 7) is much greater than
1, which is strong evidence that the duplicate has evolved under
positive selection. (After [42], based on data from [67].)Futuyma Kirkpatrick Evolution, 4e
Sinauer Associates
Troutt Visual Services
Evolution4e_14.07.ai Date 01-02-2017(B)Inside cellI IVOutside cellInside cellOutside cell(A)CO 2 –CO 2 –II+H 3 N +H 3 NIII1 2 45 63 1 2 45 63 1 2 45 63 1 2 (^4563) 1 2 (^4563)
FIGURE 14.7 Vertebrate sodium channels, which are critical to firing neurons, evolved
by duplication. (A) The α-subunit of the sodium channel protein has four domains
(labeled I–IV). Each domain has six segments that traverse the cell membrane (num-
bered in each domain). The corresponding segments in each of the four domains have
very similar protein sequences. The sodium channel protein evolved by two rounds of
duplication of a locus that coded for a single domain. (B) The ancestor of the vertebrate
sodium channel had a structure similar to this bacterial sodium channel. (After [27].)
14_EVOL4E_CH14.indd 349 3/22/17 2:44 PM