-
For the microscopic lab worm, C. elegans
-
life equates to just
a few short weeks on Earth.
-
Compare that with the tortoise,
which can age to more than 100 years.
-
Mice and rats reach the end of their lives
after just four years,
-
while for the bowhead whale,
Earth's longest-lived mammal,
-
death can come after 200.
-
Like most living things,
-
the vast majority of animals gradually
degenerate after reaching sexual maturity
-
in the process known as aging.
-
But what does it really mean to age?
-
The drivers behind this process are varied
and complicated,
-
but aging is ultimately
caused by cell death and dysfunction.
-
When we're young,
we constantly regenerate cells
-
in order to replace dead and dying ones.
-
But as we age, this process slows down.
-
In addition, older cells don't perform
their functions as well as young ones.
-
That makes our bodies go into a decline,
-
which eventually results
in disease and death.
-
But if that's consistently true,
-
why the huge variance in aging patterns
and lifespan within the animal kingdom?
-
The answer lies in several factors,
-
including environment
-
and body size.
-
These can place powerful evolutionary
pressures on animals to adapt,
-
which in turn makes the aging process
different across species.
-
Consider the cold depths of the Atlantic
and Arctic seas,
-
where Greenland sharks can live
to over 400 years,
-
and the Arctic clam known as the quahog
can live up to 500.
-
Perhaps the most impressive of these
ocean-dwelling ancients
-
is the Antarctic glass sponge,
-
which can survive over 10,000 years
in frigid waters.
-
In cold environments like these,
heartbeats and metabolic rates slow down.
-
Researchers theorize that this also
causes a slowing of the aging process.
-
In this way, the environment
shapes longevity.
-
When it comes to size,
it's often, but not always,
-
the case that larger species have a longer
lifespan than smaller ones.
-
For instance, an elephant or whale
will live much longer
-
than a mouse, rat, or vole,
-
which in turn have years on flies
and worms.
-
Some small animals, like worms and flies,
-
are also limited by the mechanics
of their cell division.
-
They're mostly made up of cells that can't
divide and be replaced when damaged,
-
so their bodies expire more quickly.
-
And size is a powerful evolutionary driver
in animals.
-
Smaller creatures are more prone
to predators.
-
A mouse, for instance, can hardly expect
to survive more than a year in the wild.
-
So, it has evolved to grow and reproduce
more rapidly,
-
like an evolutionary defense mechanism
against its shorter lifespan.
-
Larger animals, by contrast, are better
at fending off predators,
-
and so they have the luxury of time
to grow to large sizes
-
and reproduce multiple times
during their lives.
-
Exceptions to this size rule include bats,
birds, moles, and turtles,
-
but in each case, these animals have other
adaptations
-
that allow them to escape predators.
-
But there are still cases where animals
with similar defining features,
-
like size and habitat,
-
age at completely different rates.
-
In these cases, genetic differences,
-
like how each organism's cells
respond to threats,
-
often account for the discrepancies
in longevity.
-
So it's the combination
of all these factors
-
playing out to differing degrees
in different animals
-
that explains the variability we see
in the animal kingdom.
-
So what about us?
-
Humans currently have
an average life expectancy of 71 years,
-
meaning that we're not even close to being
the longest living inhabitants on Earth.
-
But we are very good at increasing
our life expectancy.
-
In the early 1900s, humans only lived
an average of 50 years.
-
Since then, we've learned to adapt
by managing many of the factors
-
that cause deaths,
-
like environmental exposure
and nutrition.
-
This, and other increases
in life expectancy
-
make us possibly the only species
on Earth
-
to take control over our natural fate.
closed TED
