How humans will evolve to survive in space | Lisa Nip | TEDxBeaconStreet

0:17 - 0:20

So there are lands
few and far between on Earth itself
0:20 - 0:24

that are hospitable to humans
by any measure,
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but survive we have.
0:26 - 0:31

Our primitive ancestors, when they found
their homes and livelihood endangered,
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they dared to make their way
into unfamiliar territories
0:34 - 0:36

in search of better opportunities.
0:36 - 0:38

And as the descendants of these explorers,
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we have their nomadic blood
coursing through our own veins.
0:43 - 0:44

But at the same time,
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distracted by our bread and circuses
0:46 - 0:50

and embroiled in the wars
that we have waged on each other,
0:50 - 0:54

it seems that we have forgotten
this desire to explore.
0:55 - 0:59

We, as a species, we're evolved uniquely
0:59 - 1:03

for Earth, on Earth, and by Earth,
1:04 - 1:07

and so content are we
with our living conditions
1:07 - 1:11

that we have grown complacent
and just too busy
1:11 - 1:13

to notice that its resources are finite,
1:13 - 1:16

and that our Sun's life is also finite.
1:17 - 1:20

While Mars and all the movies
made in its name
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have reinvigorated
the ethos for space travel,
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few of us seem to truly realize
that our species' fragile constitution
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is woefully unprepared
for long duration journeys into space.
1:33 - 1:35

Let us take a trek
to your local national forest
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for a quick reality check.
1:37 - 1:38

So just a quick show of hands here:
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how many of you think you would be able
to survive in this lush wilderness
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for a few days?
1:44 - 1:46

Well, that's a lot of you.
1:46 - 1:47

How about a few weeks?
1:48 - 1:50

That's a decent amount.
1:50 - 1:51

How about a few months?
1:52 - 1:54

That's pretty good too.
1:54 - 1:56

Now, let us imagine
that this local national forest
1:56 - 1:59

experiences an eternal winter.
2:02 - 2:05

Same questions: how many of you think you
would be able to survive for a few days?
2:06 - 2:08

That's quite a lot.
2:08 - 2:09

How about a few weeks?
2:11 - 2:13

That's still a lot more
than I would be able to.
2:13 - 2:18

So for a fun twist, let us imagine
that the only source of water available
2:18 - 2:21

is trapped as frozen blocks
miles below the surface.
2:22 - 2:26

Soil nutrients are so minimal
that no vegetation can be found,
2:26 - 2:30

and of course hardly any atmosphere
exists to speak of.
2:32 - 2:36

Such examples are only a few
of the many challenges we would face
2:36 - 2:38

on a planet like Mars.
2:39 - 2:44

So how do we steel ourselves for voyages
whose destinations are so far removed
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from a tropical vacation?
2:46 - 2:49

Will we continuously ship supplies
from Planet Earth?
2:50 - 2:53

Build space elevators,
or impossible miles of transport belts
2:53 - 2:56

that tether your planet of choice
to our home planet?
2:57 - 3:01

And how do we grow things like food
that grew up on Earth like us?
3:03 - 3:05

But I'm getting ahead of myself.
3:06 - 3:09

In our species' journey
to find a new home under a new sun,
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we are more likely than not
going to be spending much time
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in the journey itself,
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in space,
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on a ship, a hermetic flying can,
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possibly for many generations.
3:25 - 3:28

The longest continuous amount of time
that any human has spent in space
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is in the vicinity of 12 to 14 months.
3:32 - 3:35

From astronauts' experiences in space,
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we know that spending time
in a microgravity environment
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means bone loss, muscle atrophy,
cardiovascular problems,
3:43 - 3:45

among many other complications
3:45 - 3:48

that range for the physiological
to the psychological.
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And what about macrogravity,
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or any other variation
in gravitational pull
3:53 - 3:54

of the planet that we find ourselves on?
3:56 - 3:59

In short, our cosmic voyages
will be fraught with dangers
4:00 - 4:01

both known and unknown.
4:02 - 4:06

So far we've been looking to this
new piece of mechanical technology
4:06 - 4:09

or that great next generation robot
4:09 - 4:12

as part of a lineup to ensure
our species safe passage in space.
4:13 - 4:16

Wonderful as they are,
I believe the time has come
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for us to complement
these bulky electronic giants
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with what nature has already invented:
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the microbe,
4:26 - 4:31

a single-celled organism that is itself
a self-generating, self-replenishing,
4:31 - 4:32

living machine.
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It requires fairly little to maintain,
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offers much flexibility in design
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and only asks to be carried
in a single plastic tube.
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The field of study that has enabled us
to utilize the capabilities of the microbe
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is known as synthetic biology.
4:49 - 4:53

It comes from molecular biology,
which has given us antibiotics, vaccines
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and better ways to observe
the physiological nuances
4:56 - 4:57

of the human body.
4:59 - 5:01

Using the tools of synthetic biology,
5:01 - 5:04

we can now edit the genes
of nearly any organism,
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microscopic or not,
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with incredible speed and fidelity.
5:10 - 5:13

Given the limitations
of our man-made machines,
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synthetic biology will be a means for us
to engineer not only our food,
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our fuel and our environment,
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but also ourselves
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to compensate
for our physical inadequacies
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and to ensure our survival in space.
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To give you an example
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of how we can use synthetic biology
for space exploration,
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let us return to the Mars environment.
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The Martian soil composition is similar
to that of Hawaiian volcanic ash,
5:40 - 5:42

with trace amounts of organic material.
5:43 - 5:45

Let's say, hypothetically,
5:45 - 5:48

what if martian soil
could actually support plant growth
5:48 - 5:50

without using Earth-derived nutrients?
5:51 - 5:53

The first question
we should probably ask is,
5:53 - 5:56

how would we make
our plants cold-tolerant?
5:56 - 5:58

Because, on average,
the temperature on Mars
5:58 - 6:01

is a very uninviting
negative 60 degrees centigrade.
6:02 - 6:04

The next question we should ask is,
6:04 - 6:06

how do we make
our plants drought-tolerant?
6:06 - 6:09

Considering that most of the water
that forms as frost
6:09 - 6:12

evaporates more quickly
than I can say the word "evaporate."
6:13 - 6:16

Well, it turns out
we've already done things like this.
6:17 - 6:20

By borrowing genes
for anti-freeze protein from fish
6:20 - 6:24

and genes for drought tolerance
from other plants like rice
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and then stitching them
into the plants that need them,
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we now have plants that can tolerate
most droughts and freezes.
6:30 - 6:33

They're known on Earth as GMOs,
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or genetically modified organisms,
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and we rely on them to feed
all the mouths of human civilization.
6:41 - 6:44

Nature does stuff like this already,
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without our help.
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We have simply found
more precise ways to do it.
6:50 - 6:54

So why would we want to change
the genetic makeup of plants for space?
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Well, to not do so
would mean needing to engineer
6:58 - 7:02

endless acres of land
on an entirely new planet
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by releasing trillions of gallons
of atmospheric gasses
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and then constructing
a giant glass dome to contain it all.
7:09 - 7:11

It's an unrealistic engineering enterprise
7:11 - 7:15

that quickly becomes
a high-cost cargo transport mission.
7:16 - 7:17

One of the best ways to ensure
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that we will have the food supplies
and the air that we need
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is to bring with us organisms
that have been engineered
7:24 - 7:26

to adapt to new and harsh environments.
7:27 - 7:31

In essence, using engineered organisms
to help us terraform a planet
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both in the short and long term.
7:35 - 7:39

These organisms can then also
be engineered to make medicine or fuel.
7:41 - 7:44

So we can use synthetic biology
to bring highly engineered plants with us,
7:44 - 7:46

but what else can we do?
7:46 - 7:49

Well, I mentioned earlier
that we, as a species,
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were evolved uniquely for planet Earth.
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That fact has not changed much
in the last five minutes
7:55 - 7:57

that you were sitting here
and I was standing there.
7:58 - 8:02

And so, if we were to dump
any of us on Mars right this minute,
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even given ample food, water, air
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and a suit,
8:07 - 8:10

we are likely to experience
very unpleasant health problems
8:10 - 8:13

from the amount of ionizing radiation
that bombards the surface
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of planets like Mars that have little
or nonexistent atmosphere.
8:19 - 8:21

Unless we plan
to stay holed up underground
8:21 - 8:24

for the duration of our stay
on every new planet,
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we must find better ways
of protecting ourselves
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without needing to resort
to wearing a suit of armor
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that weighs something
equal to your own body weight,
8:32 - 8:34

or needing to hide behind a wall of lead.
8:36 - 8:38

So let us appeal
to nature for inspiration.
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Among the plethora of life here on Earth,
8:42 - 8:45

there's a subset of organisms
known as extremophiles,
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or lovers of extreme living conditions,
8:47 - 8:49

if you'll remember
from high school biology.
8:49 - 8:54

And among these organisms is a bacterium
by the name of Deinococcus radiodurans.
8:55 - 9:01

It is known to be able to withstand cold,
dehydration, vacuum, acid,
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and, most notably, radiation.
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While its radiation
tolerance mechanisms are known,
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we have yet to adapt
the relevant genes to mammals.
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To do so is not particularly easy.
9:13 - 9:15

There are many facets
that go into its radiation tolerance,
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and it's not as simple
as transferring one gene.
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But given a little bit of human ingenuity
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and a little bit of time,
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I think to do so is not very hard either.
9:26 - 9:32

Even if we borrow just a fraction
of its ability to tolerate radiation,
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it would be infinitely better
than what we already have,
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which is just the melanin in our skin.
9:39 - 9:41

Using the tools of synthetic biology,
9:41 - 9:44

we can harness Deinococcus
radiodurans' ability
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to thrive under otherwise
very lethal doses of radiation.
9:50 - 9:52

As difficult as it is to see,
9:52 - 9:55

homo sapiens, that is humans,
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evolves every day,
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and still continues to evolve.
10:01 - 10:03

Thousands of years of human evolution
10:03 - 10:06

has not only given us
humans like Tibetans,
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who can thrive in low-oxygen conditions,
10:08 - 10:13

but also Argentinians,
who can ingest and metabolize arsenic,
10:13 - 10:16

the chemical element
that can kill the average human being.
10:17 - 10:21

Every day, the human body evolves
by accidental mutations
10:21 - 10:23

that equally accidentally
allow certain humans
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to persevere in dismal situations.
10:27 - 10:29

But, and this is a big but,
10:30 - 10:34

such evolution requires two things
that we may not always have,
10:34 - 10:36

or be able to afford,
10:37 - 10:39

and they are death and time.
10:40 - 10:43

In our species' struggle
to find our place in the universe,
10:43 - 10:46

we may not always have the time necessary
10:46 - 10:48

for the natural evolution
of extra functions
10:48 - 10:50

for survival on non-Earth planets.
10:52 - 10:57

We're living in what E.O. Wilson
has termed the age of gene circumvention,
10:57 - 11:02

during which we remedy our genetic defects
like cystic fibrosis or muscular dystrophy
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with temporary external supplements.
11:06 - 11:07

But with every passing day,
11:08 - 11:11

we approach the age
of volitional evolution,
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a time during which we as a species
11:13 - 11:18

will have the capacity to decide
for ourselves our own genetic destiny.
11:19 - 11:21

Augmenting the human body
with new abilities
11:21 - 11:23

is no longer a question of how,
11:24 - 11:25

but of when.
11:26 - 11:28

Using synthetic biology
11:28 - 11:31

to change the genetic makeup
of any living organisms,
11:31 - 11:32

especially our own,
11:32 - 11:34

is not without its moral
and ethical quandaries.
11:35 - 11:38

Will engineering ourselves
make us less human?
11:39 - 11:41

But then again, what is humanity
11:41 - 11:44

but star stuff
that happens to be conscious?
11:45 - 11:48

Where should human genius direct itself?
11:49 - 11:53

Surely it is a bit of a waste
to sit back and marvel at it.
11:54 - 11:55

How do we use our knowledge
11:55 - 11:59

to protect ourselves
from the external dangers
11:59 - 12:01

and then protect ourselves from ourselves?
12:03 - 12:04

I pose these questions
12:04 - 12:07

not to engender the fear of science
12:07 - 12:09

but to bring to light
the many possibilities
12:09 - 12:12

that science has afforded
and continues to afford us.
12:13 - 12:17

We must coalesce as humans
to discuss and embrace the solutions
12:17 - 12:19

not only with caution
12:19 - 12:21

but also with courage.
12:23 - 12:26

Mars is a destination,
12:27 - 12:29

but it will not be our last.
12:30 - 12:33

Our true final frontier
is the line we must cross
12:33 - 12:37

in deciding what we can and should make
of our species' improbable intelligence.
12:39 - 12:43

Space is cold, brutal and unforgiving.
12:44 - 12:47

Our path to the stars
will be rife with trials
12:47 - 12:50

that will bring us to question
not only who we are
12:50 - 12:52

but where we will be going.
12:52 - 12:56

The answers will lie in our choice
to use or abandon the technology
12:56 - 12:58

that we have gleaned from life itself,
12:58 - 13:02

and it will define us for the remainder
of our term in this universe.
13:02 - 13:03

Thank you.
13:03 - 13:05

(Applause)

Title:: How humans will evolve to survive in space | Lisa Nip | TEDxBeaconStreet
Description:: If we hope to one day leave Earth and explore the universe, our bodies are going to have to get a lot better at surviving the harsh conditions of space. Using synthetic biology, Lisa Nip hopes to harness special powers from microbes on Earth — such as the ability to withstand radiation — to make humans more fit for exploring space. "We're approaching a time during which we'll have the capacity to decide our own genetic destiny," Nip says. "Augmenting the human body with new abilities is no longer a question of how, but of when."

This talk was given at a TEDx event using the TED conference format but independently organized by a local community. Learn more at http://ted.com/tedx

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Video Language:: English
Team:: closed TED
Project:: TEDxTalks
Duration:: 13:11

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