They might be called the “rats of the sky,” but
Charles Darwin certainly saw something in pigeons. It turns out the
father of evolution saw in the bird an amazing variety of variation in
color, shape and form. Richard Bailey, a photographer based in London,
honored the 150th anniversary since the publication of “On the Origin of
Species” and the 200th anniversary in 2009 of Charles Darwin’s birth by
photographing some of the pigeon breeds that played such an important
part in Darwin’s work.
Researchers have found that
mutations in pigeon DNA can control a variety of traits, including the
directions their feathers grow, like in this Jacobin pigeon. Charles Darwin
raised pigeons and was interested in their breeding as an extreme example of
domestic selection.
In the garden of his country estate, Darwin built a dovecote. He filled
it with birds he bought in London from pigeon breeders. He favored the fanciest
breeds — pouters, carriers, barbs, fantails, short-faced tumblers and many
more.
“The diversity of the breeds is something
astonishing,” he wrote a few years later in “On the Origin of Species” — a
work greatly informed by his experiments with the birds.
Pigeon breeding, Darwin argued, was an analogy for
what happened in the wild. Nature played the part of the fancier, selecting
which individuals would be able to reproduce. Natural selection might work more
slowly than human breeders, but it had far more time to produce the diversity
of life around us.
Yet to later generations of biologists, pigeons were
of little more interest than they are to, say, New Yorkers. Attention shifted
to other species, like fruit flies and E. coli.
Now Michael D. Shapiro, a biologist at the
University of Utah, is returning pigeons to the spotlight.
In an article published online last week by the journal
Science, an international team of scientists led by Dr. Shapiro reports
that it has delved into a source of information Darwin didn’t even know about:
the pigeon genome. So far, they have sequenced the DNA of 40 breeds, seeking to
pinpoint the mutations that produced their different forms.
The scientists are following Darwin’s example by
using the birds to find clues to the way evolution works in general. They are
particularly interested in the mutations that produce radically new kinds of
anatomy.
“Pigeons are an ideal way to look at these things,”
Dr. Shapiro said.
The new work supports Darwin’s original claim that
all pigeon breeds descend from the rock pigeon, whose range stretched from
Europe to North Africa and east into Asia.
“It’s a brilliant bit of investigative science, the
type of research that hopefully will come to define the genomic era,” said Beth
Shapiro (no relation to Michael), an evolutionary molecular biologist at the
University of California, Santa Cruz.
Archaeologists have speculated that rock pigeons
flocked to the first farms in the Fertile Crescent in the Middle East, where
they pecked at loose grain. Farmers then domesticated them for food.
Later, humans bred the birds to carry messages. By
the eighth century B.C., Greeks were using pigeons to send the results of
Olympic Games from town to town. Genghis Khan used pigeons to create a
communication network across his empire in 12th century A.D.
Eventually, people began breeding pigeons simply for
pleasure. Akbar the Great, a 16th-century Mughal emperor, always traveled with
his personal colony of 10,000 pigeons. He bred some of the birds for their
ability to tumble through the air, and others for their extravagant beauty.
Dr. Shapiro and his colleagues have been able to
work out the genealogy of these breeds. They found, for example, that fantail
pigeons, one of Akbar’s favorite breeds, are closely related to breeds from
Iran. Dr. Shapiro suspects that their kinship is a result of trade along the
Silk Route between the Mughal Empire and Persia.
Some of these breeds would escape from their owners
and mate with wild rock pigeons. As a result, Dr. Shapiro and his colleagues
have struggled to find a pigeon with “pure” rock pigeon DNA. In search of wild
birds, they sampled the DNA of pigeons from remote islands off the coast of
northern Scotland. “If there’s going to be any truly wild pigeons left, those
are going to be a good place to look for them,” he said.
The Scottish pigeons turned out to be closely
related to Modena pigeons, an old Italian breed that may have interbred with
the ancestors of wild pigeons in Scotland. Or perhaps Modena pigeons were
domesticated directly from wild ancestors, rather than another breed. “We just
can’t distinguish between the two possibilities yet,” Dr. Shapiro said.
European colonists brought their domesticated
pigeons to the New World, where they raised them once more for food, messages
and diversion. Thomas Jefferson designed a grand dovecote for Monticello,
complete with pillars. Some of America’s tame immigrant pigeons escaped yet
again and evolved into a new population of feral pigeons — the ones that thrive
in American cities.
“It looks like European and North American ferals
are quite distinct,” Dr. Shapiro said.
Like Darwin, Dr. Shapiro came late to the world of
pigeon breeding. From 2001 to 2006, as a postdoctoral researcher at Stanford,
he studied how stickleback fish in Canadian lakes evolved into strikingly
different shapes in just a few thousands of years. While giving a talk for the
position at the University of Utah, he had waxed poetic about how some of the
fish had lost their armored spikes.
His host was not impressed.
“He said, ‘You think sticklebacks are
diverse?’ ” Dr. Shapiro recalled. “And he plunked down an 800-page
encyclopedia on pigeon breeding and said, ‘Take a look at this.’ ”
Dr. Shapiro started leafing through the book. “I
knew a little bit about pigeons from Darwin, but this was insane,” he recalled.
When he got the job in Utah, Dr. Shapiro decided to
split his lab’s efforts between fish and pigeons. He set out to discover what
Darwin could not: the genetic basis of the birds’ evolution.
When he explained the project to pigeon breeders he
met on a visit to the Utah State Fair, they allowed him and his colleagues to
draw blood from their birds to get their DNA. Before long, Dr. Shapiro was
following Darwin’s steps and raising pigeons of his own at the university,
crossing the breeds to produce hybrids.
Once he and his colleagues worked out the genealogy
of pigeons, they could then investigate how they had evolved into so many
different forms. To begin this stage of the project, Dr. Shapiro picked out a
particularly extravagant trait to study: head crests.
“There are many different kinds of crests,” he said.
“Some birds just have just a little peak, some have what looks like an inverted
shell, some have a mane, and some have their entire head engulfed in feathers.”
Photos
of a variety of pigeons.
Dr. Shapiro and his colleagues have found that the
closest relatives of crested breeds are uncrested breeds. In other words,
pigeon breeders produced crests on the birds on five separate
occasions. The scientists compared the genomes of the crested pigeons with
one another, as well as with other pigeons and with chickens, turkeys and other
species. They hunted for mutated genes unique to the crested breeds, and found
that all of them shared precisely the same mutation in precisely the same gene,
EphB2.
Bird embryos develop placodes, little disks of
tissue on their skin from which feathers will grow. The scientists found that
in ordinary pigeons without crests, EphB2 became active on the bottom edge of
the placodes; in crested pigeons it was active on the top edge.
The experiment suggests that EphB2 tells the placode
which way is up. In most pigeons, it instructs the feathers to grow down the
neck; but the mutation changes the location where EphB2 switches on, effectively
turning the feathers upside down and producing a crest.
“They grow the wrong way,” Dr. Shapiro said.
“They’re even pointing the wrong way in the embryo, before they become
feathers.”
The new research suggests that the crested version
of EphB2 arose in a surprising way. It mutated only once, rather than five
separate times.
Dr. Shapiro came to this conclusion in part because
he found that it takes two copies of the mutant gene to reverse the feathers.
When the mutation arose, it was passed down invisibly from pigeon to pigeon.
Only when two carriers happened to mate did they suddenly produce a crested
chick.
Adam Boyko, a Cornell geneticist who studies dogs,
has found similar results in his own research.
Several dog breeds have short legs, for example, but
only a single mutant gene is responsible for the change. Like the
crested-feather mutation, it worked its way into each of the short-legged
breeds. “There’s clearly a parallel,” Dr. Boyko said.
Dr. Shapiro is moving ahead with studies on the many
other traits of pigeon breeds to see if this pattern is an exception or the
rule.
“The more examples that we have,” he said, “the more
we can understand what the general trends in evolutionary change are.”
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