Published June 26, 2013
DNA shines a light back into the past, showing us things that fossils can't. But how far back can that light extend?
Some of the oldest DNA sequences come from mastodon and polar bear fossils about 50,000 and 110,000 years old, respectively. But a new study published online today in the journal Nature
reports the latest in the push for recovering ever more ancient DNA
sequences. Samples from a horse leg bone more than 700,000 years old
have yielded the oldest full genome known to date.
"We knew that sequencing ancient genomes as old as 70,000 to 80,000 years old was possible," said Ludovic Orlando,
an evolutionary geneticist with the Natural History Museum of Denmark
at the University of Copenhagen. "So we said, why not try even further
back in time?"
The Pleistocene
horse genome Orlando and colleagues pieced together helped them
determine that the ancestor to the Equus lineage—the group that gave
rise to modern horses, zebras, and donkeys—arose 4 to 4.5 million years
ago, or about two million years earlier than previously thought. (Learn more about the evolution of horses.)
The
ancient horse genome also allowed the team to determine the
evolutionary relationship between modern domestic horses and the
endangered Przewalski's horse, a native to the Mongolian steppes that represents the last living breed of wild horse.
The
team found that Przewalski's horses were an offshoot of the lineage
that gave rise to domestic horses. The two groups diverged around 50,000
years ago.
Once considered extinct in the wild,
Przewalski's horse was re-introduced into the wild from a captive
population of only a few dozen. While this number suggests that the
genetic diversity of the species might be too small to support, the
study shows that Przewalski's horses are in fact more genetically
diverse than domestic breeds such as Arabian and Icelandic horses.
"We
think that there's enough genetic diversity within the Przewalski's
horse to keep conservation efforts viable," Orlando said.
Cold Storage
Extracting ancient genomes from long-dead samples is labor intensive, and there is a limit to how far back one can go.
Studies on the half-life of DNA
suggest that even under ideal circumstances, DNA sequences older than
1.5 million years will be too short to be readable. So it's highly
unlikely that DNA will be recovered from dinosaurs, since they
disappeared 65 million years ago, except for the lineage leading to
modern birds.
But the preservation environment of an
ancient sample can help extend the amount of time DNA has before it
degrades past the point of being recoverable.
"Cold is good," said Orlando. Frozen is even better, because liquid water isn't present to degrade DNA molecules.
The
six-inch (15-centimeter) horse leg bone the team analyzed originated in
the Yukon Territory of western Canada. Permafrost kept the remains in a
kind of cold storage for about 735,000 years until scientists dug it
out in 2003.
To determine whether there might be any
biological molecules left in the sample, Orlando and colleagues first
looked to see if they could spot amino acids from collagen—a protein
found in bone—in the specimen.
Once they identified and
successfully sequenced those proteins, the researchers moved on to
trying to extract DNA from the ancient leg bone.
As is
the case with the majority of ancient fossils, most of the DNA they
found was from bacteria that had populated the bone after the horse
died. Using DNA from modern horses as a reference, the team was able to
identify "endogenous" DNA that belonged to the ancient horse itself.
"We
sequenced 12 billion DNA molecules, of which 40 million [were of] horse
origin," said Orlando. "There was a bit of horse DNA in an ocean of
microbial DNA."
A New World
The
recovery of a genome almost an order of magnitude older than any
previous genomic information opens up a wide range of new targets for
studying fossils at the genetic level, possibly including ancient human
species, if they lived in cooler environments.
"You name it—what are your favorite Pleistocene beasts?" wrote Hendrik Poinar, an evolutionary geneticist at McMaster University in Ontario, Canada, in an email.
Poinar,
who was not involved in the current study, would like to see this
applied to elephant evolution. "This should address issues related to
the origin of hair and size plasticity and how they adapted to very
different ecologies."
He was not surprised that
researchers were able to sequence a complete genome from 700,000 years
ago. It just takes time and money, Poinar said.
But he
also points out that sequencing ancient genomes is more about
preservation in various environments than the age of a specimen. "I am
sure there will be older genomes soon enough."
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