Lonesome
George was the last known individual of the Galapagos tortoise subspecies
Geochelone nigra abingdoni. He died in 2012.
Rationally,
people had time to prepare for the reality that George would one day fade away,
and with him, an entire lineage. He had lived for a century or more, a common
life expectancy for giant tortoises, and all attempts to mate him during his
last few decades were unsuccessful.
But
emotionally, it’s hard to brace oneself for the realization that something that
was once there is finally, completely gone. It’s the kind of stuff that makes
you ponder life, our fleeting stint in the universe and the unrelenting,
forward march of time
Similar
feelings drive longevity research. Recently, a team of scientists turned to
George for help in this search, mining his genetic code for clues to his long
life span.
In a
paper published Monday in Nature Ecology & Evolution, the researchers
reported preliminary findings of gene variants in
George linked with a robust immune system, efficient DNA repair and resistance
to cancer. The study also sets the stage for understanding
giant tortoises’ evolutionary past, which might help to conserve them in the
future.
Giant
tortoises helped launch the theory of evolution. When Charles Darwin visited
the Galápagos, he noticed the
tortoises’ shell shapes were unique adaptations to their
environments. He hypothesized that natural selection was at work.
The
Galápagos tortoises have since continued to be a rich source of inquiry for
evolutionary scientists. Adalgisa “Gisella” Caccone, a researcher at Yale
University, has spent decades studying the reptiles that are the size of
upright pianos.
But years
ago, Dr. Caccone hit a wall — she needed someone to help her decipher which
parts of the tortoises’ DNA were functional genes, which regions were not and
what the genes’ functions might be.
She
received a fateful message from Carlos López-Otín, a professor at the
University of Oviedo in Spain who has built a career studying cancer and aging
in humans. Dr. López-Otín was interested in unlocking the genetic secrets
behind giant tortoises’ legendary longevity.
Dr.
Caccone loved the idea of “a conservation icon providing insights” into human
health and longevity. The scientists sequenced the entire genome of Lonesome
George, plus that of an Aldabra giant tortoise from the Seychelles, another
extraordinarily long-lived species (one was rumored to have lived up to 250 years
in captivity).
The
researchers then compared the tortoise genomes with those of mammals, fish,
birds and other reptiles, looking for discrepancies that could affect aging.
The scientists found evidence that a mutation in a gene called IGF1R, which has
been linked with longevity in humans and mice, might contribute to the
tortoises’ exceptional life span.
They also
discovered that the tortoises had more copies of genes related to energy
regulation, DNA repair, tumor suppression and immune defense compared with
other creatures. While most mammals have only one copy of a gene involved in
immune response called PRF1, for instance, both tortoises had a whopping 12
copies in their genome.
Generally,
having many copies of genes can allow existing functions to occur more
efficiently, or provide fuel for the evolution of new functions.
The
research opens the door to learning more about tortoise biology, too. Dr.
Caccone plans to dive deep into the genomes to piece together how giant
tortoises evolved traits like gigantism and carapace shape. Genomic data will
also aid her
efforts to revive two extinct species of Galápagos tortoise.
Future
avenues of research will only expand as scientists sequence the genomes of more
reptiles, said Kenro Kusumi, a professor of life sciences at Arizona State
University.
There are
many lessons to learn from reptiles. They are the closest relatives of humans
that can regenerate entire body parts,
a trait that could inform medical treatments.
And many
reptiles, including tortoises, can enter an inactive state that allows them to
survive extreme conditions. The ability to induce similar states in humans
could be useful for future space travel, Dr. Kusumi said.
“The
beauty of having these genomes is that it’s a great starting point to ask
questions,” he added. “Even after death, Lonesome George is teaching us things
— just like his ancestors taught Charles Darwin.”
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