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Billions of years ago
on the young planet Earth
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simple organic compounds assembled
into more complex coalitions
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that could grow and reproduce.
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They were the very first life on Earth,
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and they gave rise to every one
of the billions of species
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that have inhabited our planet since.
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At the time, Earth was almost completely
devoid
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of what we’d recognize as a suitable
environment for living things.
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The young planet had widespread
volcanic activity
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and an atmosphere that created
hostile conditions.
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So where on Earth could life begin?
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To begin the search for
the cradle of life,
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it’s important to first understand the
basic necessities for any life form.
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Elements and compounds essential to life
include hydrogen, methane, nitrogen,
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carbon dioxide, phosphates, and ammonia.
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In order for these ingredients to comingle
and react with each other,
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they need a liquid solvent: water.
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And in order to grow and reproduce,
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all life needs a source of energy.
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Life forms are divided into two camps:
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autotrophs, like plants, that generate
their own energy,
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and heterotrophs, like animals, that
consume other organisms for energy.
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The first life form wouldn’t have had
other organisms to consume, of course,
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so it must have been an autotroph,
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generating energy either from the sun
or from chemical gradients.
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So what locations meet these criteria?
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Places on land or close to the surface
of the ocean
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have the advantage of access to sunlight.
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But at the time when life began,
the UV radiation on Earth’s surface
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was likely too harsh for life
to survive there.
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One setting offers protection
from this radiation
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and an alternative energy source:
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the hydrothermal vents that wind across
the ocean floor,
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covered by kilometers of seawater
and bathed in complete darkness.
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A hydrothermal vent is a fissure
in the Earth’s crust
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where seawater seeps into magma
chambers
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and is ejected back out
at high temperatures,
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along with a rich slurry of minerals
and simple chemical compounds.
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Energy is particularly concentrated
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at the steep chemical gradients
of hydrothermal vents.
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There’s another line of evidence
that points to hydrothermal vents:
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the Last Universal Common Ancestor
of life, or LUCA for short.
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LUCA wasn’t the first life form,
but it’s as far back as we can trace.
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Even so, we don’t actually know what
LUCA looked like—
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there’s no LUCA fossil, no modern-day
LUCA still around—
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instead, scientists identified genes that
are commonly found in species
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across all three domains
of life that exist today.
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Since these genes are shared across
species and domains,
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they must have been inherited from
a common ancestor.
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These shared genes tell us that LUCA lived
in a hot, oxygen-free place
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and harvested energy from a chemical
gradient—
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like the ones at hydrothermal vents.
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There are two kinds of hydrothermal vent:
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black smokers and white smokers.
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Black smokers release acidic,
carbon-dioxide-rich water,
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heated to hundreds of degrees Celsius
and packed with sulphur, iron, copper,
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and other metals essential to life.
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But scientists now believe that black
smokers were too hot for LUCA—
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so now the top candidates for the
cradle of life are white smokers.
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Among the white smokers,
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a field of hydrothermal vents on the
Mid-Atlantic Ridge called Lost City
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has become the most favored candidate
for the cradle of life.
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The seawater expelled here is highly
alkaline and lacks carbon dioxide,
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but is rich in methane and offers
more hospitable temperatures.
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Adjacent black smokers may have
contributed the carbon dioxide necessary
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for life to evolve at Lost City,
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giving it all the components to support
the first organisms
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that radiated into the incredible
diversity of life on earth today.
closed TED
Florencia Bracamonte
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Вадим Гузик
There's a typo: commingle (1.05)