Finding life we can't imagine | Christoph Adami | TEDxUIUC

0:10 - 0:12

So, I have a strange career.
0:13 - 0:16

I know it because people come up to me,
like colleagues, and say,
0:16 - 0:18

"Chris, you have a strange career."
0:18 - 0:19

(Laughter)
0:20 - 0:21

And I can see their point,
0:21 - 0:26

because I started my career
as a theoretical nuclear physicist.
0:26 - 0:31

And I was thinking about quarks
and gluons and heavy ion collisions,
0:31 - 0:32

and I was only 14 years old...
0:33 - 0:36

No, no, I wasn't 14 years old.
0:37 - 0:38

But after that,
0:39 - 0:41

I actually had my own lab
0:41 - 0:43

in the Computational
Neuroscience department,
0:43 - 0:45

and I wasn't doing any neuroscience.
0:45 - 0:48

Later, I would work
on evolutionary genetics,
0:48 - 0:50

and I would work on systems biology.
0:50 - 0:53

But I'm going to tell you
about something else today.
0:53 - 0:57

I'm going to tell you
about how I learned something about life.
0:57 - 1:01

And I was actually a rocket scientist.
1:01 - 1:03

I wasn't really a rocket scientist,
1:03 - 1:07

but I was working
at the Jet Propulsion Laboratory
1:08 - 1:10

in sunny California, where it's warm;
1:10 - 1:14

whereas now I am
in the mid-West, and it's cold.
1:14 - 1:17

But it was an exciting experience.
1:17 - 1:20

One day, a NASA manager
comes into my office,
1:20 - 1:23

sits down and says
1:24 - 1:25

that's my office, right there,
1:25 - 1:29

and I had a nice office
with the sun shining... anyway -
1:30 - 1:31

He said, "Chris,
1:32 - 1:36

can you please tell us,
how do we look for life outside Earth?"
1:37 - 1:39

And that came as a surprise to me,
1:39 - 1:43

because I was actually hired
to work on quantum computation.
1:44 - 1:45

Yet, I had a very good answer.
1:45 - 1:47

I said, "I have no idea."
1:47 - 1:48

(Laughter)
1:48 - 1:53

And he told me, "Biosignatures,
we need to look for a biosignature."
1:53 - 1:55

And I said, "What is that?"
1:55 - 1:57

And he said, "It's any
measurable phenomenon
1:57 - 2:00

that allows us to indicate
the presence of life."
2:01 - 2:02

And I said, "Really?
2:03 - 2:05

Because isn't that easy?
2:05 - 2:06

I mean, we have life.
2:08 - 2:10

Can't you apply a definition,
2:10 - 2:14

for example, a Supreme Court-like
definition of life?"
2:15 - 2:18

And then I thought about it
a little bit, and I said,
2:18 - 2:19

"Well, is it really that easy?
2:19 - 2:21

Because, yes, if you see
something like this,
2:21 - 2:24

then all right, fine,
I'm going to call it life...
2:24 - 2:25

No doubt about it.
2:25 - 2:27

But here's something."
2:27 - 2:30

And he goes, "Right,
that's life too. I know that."
2:30 - 2:35

Except, if you think that life
is also defined by things that die,
2:35 - 2:37

you're not in luck with this thing,
2:37 - 2:39

because that's actually
a very strange organism.
2:39 - 2:41

It grows up into the adult stage like that
2:41 - 2:43

and then goes through
a Benjamin Button phase,
2:43 - 2:49

and actually goes backwards and backwards
until it's like a little embryo again,
2:49 - 2:51

and then actually grows back up,
and back down and back up...
2:51 - 2:53

Sort of yo-yo... and it never dies.
2:53 - 2:56

So it's actually life,
2:56 - 3:00

but it's actually not
as we thought life would be.
3:01 - 3:03

And then you see something like that.
3:03 - 3:06

And he was like, "My God,
what kind of a life form is that?"
3:06 - 3:07

Anyone know?
3:07 - 3:10

It's actually not life, it's a crystal.
3:11 - 3:14

So once you start looking and looking
at smaller and smaller things...
3:14 - 3:18

So this particular person wrote
a whole article and said,
3:18 - 3:20

"Hey, these are bacteria."
3:20 - 3:22

Except, if you look a little bit closer,
3:22 - 3:26

you see, in fact, that this thing
is way too small to be anything like that.
3:26 - 3:29

So he was convinced,
but, in fact, most people aren't.
3:30 - 3:33

And then, of course,
NASA also had a big announcement,
3:33 - 3:36

and President Clinton
gave a press conference,
3:36 - 3:42

about this amazing discovery
of life in a Martian meteorite.
3:43 - 3:46

Except that nowadays,
it's heavily disputed.
3:47 - 3:50

If you take the lesson
of all these pictures,
3:50 - 3:52

then you realize, well, actually,
maybe it's not that easy.
3:52 - 3:56

Maybe I do need a definition of life
3:56 - 3:58

in order to make that kind of distinction.
3:59 - 4:02

So can life be defined?
4:02 - 4:04

Well how would you go about it?
4:04 - 4:08

Well of course, you'd go
to Encyclopedia Britannica and open at L.
4:08 - 4:11

No, of course you don't do that;
you put it somewhere in Google.
4:11 - 4:12

And then you might get something.
4:12 - 4:14

(Laughter)
4:14 - 4:15

And what you might get...
4:15 - 4:19

And anything that actually refers
to things that we are used to,
4:19 - 4:20

you throw away.
4:20 - 4:22

And then you might come up
with something like this.
4:22 - 4:24

And it says something longwinded
4:26 - 4:29

complicated,
with lots and lots of concepts.
4:30 - 4:35

Who on Earth would write something
as convoluted and complex and inane?
4:37 - 4:41

Oh, it's actually a really, really,
important set of concepts.
4:41 - 4:43

So I'm highlighting just a few words
4:43 - 4:48

and saying definitions
like that rely on things
4:48 - 4:54

that are not based on amino acids
or leaves or anything that we are used to,
4:54 - 4:55

but in fact on processes only.
4:55 - 4:57

And if you take a look at that,
4:57 - 5:01

this was actually in a book that I wrote
that deals with artificial life.
5:01 - 5:05

And that explains why that NASA manager
was actually in my office to begin with.
5:05 - 5:08

Because the idea was that,
with concepts like that,
5:08 - 5:12

maybe we can actually
manufacture a form of life.
5:12 - 5:17

And so if you go and ask yourself,
"What on Earth is artificial life?",
5:17 - 5:21

let me give you a whirlwind tour
of how all this stuff came about.
5:21 - 5:25

And it started out quite a while ago,
5:25 - 5:29

when someone wrote one of the first
successful computer viruses.
5:30 - 5:32

And for those of you
who aren't old enough,
5:32 - 5:34

you have no idea
how this infection was working...
5:34 - 5:37

Namely, through these floppy disks.
5:37 - 5:41

But the interesting thing
about these computer virus infections
5:41 - 5:45

was that, if you look at the rate
at which the infection worked,
5:45 - 5:49

they show this spiky behavior
that you're used to from a flu virus.
5:49 - 5:51

And it is in fact due to this arms race
5:51 - 5:55

between hackers
and operating system designers
5:55 - 5:56

that things go back and forth.
5:56 - 6:01

And the result is kind of
a tree of life of these viruses,
6:01 - 6:05

a phylogeny that looks very much
like the type of life
6:05 - 6:07

that we're used to,
at least on the viral level.
6:07 - 6:08

So is that life?
6:09 - 6:10

Not as far as I'm concerned.
6:10 - 6:13

Why? Because these things
don't evolve by themselves.
6:13 - 6:15

In fact, they have hackers writing them.
6:15 - 6:19

But the idea was taken
very quickly a little bit further,
6:19 - 6:23

when a scientist working
at the Santa Fe Institute decided,
6:23 - 6:26

"Why don't we try to package
these little viruses
6:26 - 6:29

in artificial worlds
inside of the computer
6:29 - 6:30

and let them evolve?"
6:30 - 6:31

And this was Steen Rasmussen.
6:31 - 6:34

And he designed this system,
but it really didn't work,
6:34 - 6:37

because his viruses
were constantly destroying each other.
6:37 - 6:42

But there was another scientist
who had been watching this, an ecologist.
6:42 - 6:44

And he went home and says,
"I know how to fix this."
6:44 - 6:46

And he wrote the Tierra system,
6:46 - 6:47

and, in my book,
6:47 - 6:51

is in fact one of the first
truly artificial living systems...
6:51 - 6:55

Except for the fact that these programs
didn't really grow in complexity.
6:55 - 6:58

So having seen this work,
worked a little bit on this,
6:58 - 6:59

this is where I came in.
6:59 - 7:03

And I decided to create a system
that has all the properties
7:03 - 7:07

that are necessary to see, in fact,
the evolution of complexity,
7:07 - 7:10

more and more complex
problems constantly evolving.
7:10 - 7:14

And of course, since I really don't know
how to write code, I had help in this.
7:14 - 7:16

I had two undergraduate students
7:16 - 7:18

at California Institute of Technology
that worked with me.
7:19 - 7:22

That's Charles Ofria on the left,
Titus Brown on the right.
7:22 - 7:25

They are now, actually,
respectable professors
7:25 - 7:27

at Michigan State University,
7:27 - 7:32

but I can assure you, back in the day,
we were not a respectable team.
7:32 - 7:34

And I'm really happy
that no photo survives
7:34 - 7:36

of the three of us
anywhere close together.
7:37 - 7:39

But what is this system like?
7:39 - 7:41

Well I can't really go into the details,
7:41 - 7:44

but what you see here
is some of the entrails.
7:44 - 7:48

But what I wanted to focus on
is this type of population structure.
7:48 - 7:50

There's about 10,000
programs sitting here.
7:50 - 7:53

And all different strains
are colored in different colors.
7:53 - 7:57

And as you see here, there are groups
that are growing on top of each other,
7:57 - 7:58

because they are spreading.
7:58 - 8:03

Any time there is a program
that's better at surviving in this world,
8:03 - 8:05

due to whatever mutation it has acquired,
8:05 - 8:08

it is going to spread over the others
and drive the others to extinction.
8:08 - 8:10

So I'm going to show you a movie
8:10 - 8:12

where you're going to see
that kind of dynamic.
8:12 - 8:16

And these kinds of experiments are started
with programs that we wrote ourselves.
8:16 - 8:20

We write our own stuff, replicate it,
and are very proud of ourselves.
8:20 - 8:22

And we put them in,
and what you see immediately
8:22 - 8:25

is that there are waves
and waves of innovation.
8:25 - 8:27

By the way, this is highly accelerated,
8:27 - 8:30

so it's like a 1000 generations a second.
8:30 - 8:34

But immediately, the system goes like,
"What kind of dumb piece of code was this?
8:34 - 8:38

This can be improved upon
in so many ways, so quickly."
8:38 - 8:42

So you see waves of new types
taking over the other types.
8:42 - 8:44

And this type of activity
goes on for quite a while,
8:44 - 8:49

until the main easy things
have been acquired by these programs.
8:50 - 8:53

And then, you see
sort of like a stasis coming on
8:54 - 8:56

where the system essentially waits
8:56 - 8:59

for a new type of innovation,
like this one,
9:00 - 9:04

which is going to spread over
all the other innovations that were before
9:04 - 9:07

and is erasing the genes
that it had before,
9:07 - 9:11

until a new type of higher level
of complexity has been achieved.
9:11 - 9:14

And this process goes on and on and on.
9:14 - 9:16

So what we see here
9:16 - 9:20

is a system that lives in very much
the way we're used to how life goes.
9:21 - 9:25

But what the NASA people
had asked me really was,
9:25 - 9:28

"Do these guys have a biosignature?
9:29 - 9:30

Can we measure this type of life?
9:30 - 9:32

Because if we can,
9:32 - 9:35

maybe we have a chance of actually
discovering life somewhere else
9:36 - 9:39

without being biased
by things like amino acids."
9:39 - 9:41

So I sat down a little bit,
9:41 - 9:43

and I said, "Well, if we do this,
9:43 - 9:46

perhaps we should construct a biosignature
9:47 - 9:52

that is based on life
as a universal process.
9:52 - 9:57

In fact, it should perhaps make use
of the concepts that I developed
9:57 - 10:01

just in order to sort of capture
what a simple living system might be."
10:02 - 10:03

And the thing I came up with...
10:03 - 10:07

I have to first give you
an introduction about the idea,
10:07 - 10:11

and maybe that would be
a meaning detector,
10:11 - 10:12

rather than a life detector.
10:13 - 10:15

And the way we would do that...
10:15 - 10:17

I would like to find out
how I can distinguish text
10:17 - 10:22

that was written by a million monkeys,
as opposed to text that is in our books.
10:23 - 10:25

And I would like to do it in such a way
10:25 - 10:28

that I don't actually have to be able
to read the language,
10:28 - 10:30

because I'm sure I won't be able to.
10:30 - 10:32

As long as I know
that there's some sort of alphabet.
10:32 - 10:35

So here would be a frequency plot
10:35 - 10:39

of how often you find
each of the 26 letters of the alphabet
10:39 - 10:41

in a text written by random monkeys.
10:43 - 10:48

And obviously, each of these letters
comes off about roughly equally frequent.
10:48 - 10:51

But if you now look at the same
distribution in English texts,
10:52 - 10:53

it looks like that.
10:54 - 10:57

And I'm telling you,
this is very robust across English texts.
10:57 - 11:00

And if I look at French texts,
it looks a little bit different,
11:00 - 11:02

or Italian or German.
11:02 - 11:05

They all have their own type
of frequency distribution,
11:05 - 11:07

but it's robust.
11:07 - 11:10

It doesn't matter whether it writes
about politics or about science.
11:10 - 11:16

It doesn't matter whether it's a poem
or whether it's a mathematical text.
11:16 - 11:17

It's a robust signature,
11:17 - 11:19

and it's very stable.
11:19 - 11:21

As long as our books
are written in English...
11:22 - 11:24

Because people are rewriting them
and recopying them...
11:24 - 11:26

It's going to be there.
11:26 - 11:32

So that inspired me to think about,
well, what if I try to use this idea
11:32 - 11:36

in order, not to detect random texts
from texts with meaning,
11:36 - 11:39

but rather detect the fact
that there is meaning
11:39 - 11:42

in the biomolecules that make up life.
11:42 - 11:43

But first I have to ask:
11:43 - 11:45

what are these building blocks,
11:45 - 11:48

like the alphabet, elements
that I showed you?
11:48 - 11:51

Well it turns out, we have
many different alternatives
11:51 - 11:54

for such a set of building blocks.
11:54 - 11:55

We could use amino acids,
11:55 - 11:58

we could use nucleic acids,
carboxylic acids, fatty acids.
11:58 - 12:01

In fact, chemistry's extremely rich,
and our body uses a lot of them.
12:01 - 12:04

So that we actually, to test this idea,
12:04 - 12:07

first took a look at amino acids
and some other carboxylic acids.
12:07 - 12:09

And here's the result.
12:10 - 12:13

Here is, in fact, what you get
12:13 - 12:16

if you, for example, look
at the distribution of amino acids
12:17 - 12:21

on a comet or in interstellar space
or, in fact, in a laboratory,
12:21 - 12:25

where you made very sure
that in your primordial soup,
12:25 - 12:26

there is no living stuff in there.
12:28 - 12:33

What you find is mostly
glycine and then alanine
12:33 - 12:35

and there's some trace elements
of the other ones.
12:35 - 12:37

That is also very robust...
12:38 - 12:41

What you find in systems like Earth
12:41 - 12:45

where there are amino acids,
but there is no life.
12:45 - 12:49

But suppose you take some dirt
and dig through it
12:49 - 12:52

and then put it into these spectrometers,
12:52 - 12:54

because there's bacteria
all over the place;
12:54 - 12:57

or you take water anywhere on Earth,
12:57 - 12:58

because it's teaming with life,
12:58 - 13:00

and you make the same analysis;
13:00 - 13:03

the spectrum looks completely different.
13:03 - 13:06

Of course, there is still
glycine and alanine,
13:06 - 13:09

but in fact, there are these heavy
elements, these heavy amino acids,
13:09 - 13:13

that are being produced
because they are valuable to the organism.
13:14 - 13:18

And some other ones
that are not used in the set of 20,
13:18 - 13:21

they will not appear at all
in any type of concentration.
13:22 - 13:24

So this also turns out
to be extremely robust.
13:24 - 13:27

It doesn't matter what kind of sediment
you're using to grind up,
13:27 - 13:31

whether it's bacteria
or any other plants or animals.
13:31 - 13:32

Anywhere there's life,
13:32 - 13:34

you're going to have this distribution,
13:34 - 13:36

as opposed to that distribution.
13:36 - 13:39

And it is detectable
not just in amino acids.
13:40 - 13:41

Now you could ask:
13:41 - 13:44

Well, what about these Avidians?
13:44 - 13:48

The Avidians being the denizens
of this computer world
13:48 - 13:51

where they are perfectly happy
replicating and growing in complexity.
13:51 - 13:56

So this is the distribution that you get
if, in fact, there is no life.
13:56 - 13:59

They have about 28 of these instructions.
13:59 - 14:02

And if you have a system where
they're being replaced one by the other,
14:02 - 14:04

it's like the monkeys
writing on a typewriter.
14:04 - 14:09

Each of these instructions
appears with roughly the equal frequency.
14:10 - 14:14

But if you now take
a set of replicating guys
14:14 - 14:16

like in the video that you saw,
14:16 - 14:18

it looks like this.
14:19 - 14:20

So there are some instructions
14:20 - 14:23

that are extremely valuable
to these organisms,
14:23 - 14:25

and their frequency is going to be high.
14:25 - 14:29

And there's actually some instructions
that you only use once, if ever.
14:29 - 14:30

So they are either poisonous
14:30 - 14:35

or really should be used
at less of a level than random.
14:35 - 14:37

In this case, the frequency is lower.
14:38 - 14:41

And so now we can see,
is that really a robust signature?
14:41 - 14:42

I can tell you indeed it is,
14:42 - 14:46

because this type of spectrum,
just like what you've seen in books,
14:46 - 14:48

and just like what you've seen
in amino acids,
14:48 - 14:50

it doesn't really matter
how you change the environment,
14:51 - 14:53

it's very robust, it's going
to reflect the environment.
14:53 - 14:56

So I'm going to show you now
a little experiment that we did.
14:56 - 14:58

And I have to explain to you,
14:58 - 14:59

the top of this graph
14:59 - 15:02

shows you that frequency
distribution that I talked about.
15:02 - 15:07

Here, that's the lifeless environment
15:07 - 15:11

where each instruction occurs
at an equal frequency.
15:12 - 15:17

And below there, I show, in fact,
the mutation rate in the environment.
15:17 - 15:20

And I'm starting this
at a mutation rate that is so high
15:20 - 15:24

that even if you would drop
a replicating program
15:24 - 15:28

that would otherwise happily grow up
to fill the entire world,
15:28 - 15:31

if you drop it in, it gets mutated
to death immediately.
15:31 - 15:37

So there is no life possible
at that type of mutation rate.
15:37 - 15:41

But then I'm going to slowly
turn down the heat, so to speak,
15:41 - 15:43

and then there's this viability threshold
15:43 - 15:47

where now it would be possible
for a replicator to actually live.
15:47 - 15:52

And indeed, we're going to be dropping
these guys into that soup all the time.
15:53 - 15:54

So let's see what that looks like.
15:54 - 15:57

So first, nothing, nothing, nothing.
15:57 - 15:59

Too hot, too hot.
15:59 - 16:01

Now the viability threshold is reached,
16:02 - 16:06

and the frequency distribution
has dramatically changed
16:06 - 16:07

and, in fact, stabilizes.
16:08 - 16:09

And now what I did there
16:09 - 16:13

is, I was being nasty,
I just turned up the heat again and again.
16:13 - 16:15

And of course, it reaches
the viability threshold.
16:15 - 16:18

And I'm just showing this to you
again because it's so nice.
16:18 - 16:19

You hit the viability threshold.
16:20 - 16:22

The distribution changes to "alive!"
16:22 - 16:26

And then, once you hit the threshold
16:26 - 16:30

where the mutation rate is so high
that you cannot self-reproduce,
16:30 - 16:36

you cannot copy the information
forward to your offspring
16:36 - 16:41

without making so many mistakes
that your ability to replicate vanishes.
16:41 - 16:42

And then, that signature is lost.
16:44 - 16:46

What do we learn from that?
16:46 - 16:50

Well, I think we learn
a number of things from that.
16:50 - 16:51

One of them is,
16:52 - 16:57

if we are able to think about life
in abstract terms...
16:57 - 16:59

And we're not talking
about things like plants,
16:59 - 17:01

and we're not talking about amino acids,
17:01 - 17:03

and we're not talking about bacteria,
17:03 - 17:05

but we think in terms of processes...
17:05 - 17:07

Then we could start to think about life
17:08 - 17:10

not as something
that is so special to Earth,
17:10 - 17:13

but that, in fact, could exist anywhere.
17:13 - 17:17

Because it really only has to do
with these concepts of information,
17:17 - 17:21

of storing information
within physical substrates...
17:21 - 17:25

Anything: bits, nucleic acids,
anything that's an alphabet...
17:25 - 17:27

And make sure that there's some process
17:27 - 17:31

so that this information can be stored
for much longer than you would expect...
17:31 - 17:36

The time scales for
the deterioration of information.
17:36 - 17:39

And if you can do that,
then you have life.
17:39 - 17:41

So the first thing that we learn
17:41 - 17:46

is that it is possible to define life
in terms of processes alone,
17:46 - 17:51

without referring at all
to the type of things that we hold dear,
17:51 - 17:54

as far as the type of life on Earth is.
17:54 - 17:57

And that, in a sense, removes us again,
17:57 - 18:00

like all of our scientific discoveries,
or many of them...
18:00 - 18:02

It leads to s continuous
dethroning of man...
18:02 - 18:05

Of how we think we're special
because we're alive.
18:05 - 18:08

Well, we can make life;
we can make life in the computer.
18:08 - 18:11

Granted, it's limited,
18:11 - 18:16

but we have learned what it takes
in order to actually construct it.
18:16 - 18:18

And once we have that,
18:19 - 18:21

then it is not such
a difficult task anymore
18:21 - 18:25

to say, if we understand
the fundamental processes
18:25 - 18:29

that do not refer
to any particular substrate,
18:29 - 18:32

then we can go out and try other worlds,
18:33 - 18:36

figure out what kind of chemical
alphabets might there be,
18:37 - 18:42

figure enough about the normal chemistry,
the geochemistry of the planet,
18:42 - 18:46

so that we know what this distribution
would look like in the absence of life,
18:46 - 18:49

and then look for large
deviations from this...
18:49 - 18:54

This thing sticking out, which says,
"This chemical really shouldn't be there."
18:54 - 18:56

Now we don't know that there's life then,
18:56 - 18:57

but we could say,
18:57 - 19:01

"Well at least I'm going to have to take
a look very precisely at this chemical
19:01 - 19:03

and see where it comes from."
19:03 - 19:06

And that might be our chance
of actually discovering life
19:07 - 19:09

when we cannot visibly see it,
19:09 - 19:11

as I've shown you.
19:12 - 19:16

And so that's really the only
take-home message that I have for you.
19:16 - 19:21

Life can be less mysterious
than we make it out to be
19:21 - 19:24

when we try to think
about how it would be on other planets.
19:24 - 19:28

And if we remove the mystery of life,
19:28 - 19:33

then I think it is a little bit easier
for us to think about how we live,
19:33 - 19:36

and how perhaps we're not as special
as we always think we are.
19:36 - 19:38

And I'm going to leave you with that.
19:38 - 19:40

And thank you very much.
19:40 - 19:42

(Applause)

Title:: Finding life we can't imagine | Christoph Adami | TEDxUIUC
Description:: How do we search for alien life if it's nothing like the life that we know? Christoph Adami shows how he uses his research into artificial life -- self-replicating computer programs -- to find a signature, a "biomarker," that is free of our preconceptions of what life is.

more » « less
Video Language:: English
Team:: closed TED
Project:: TEDxTalks
Duration:: 19:51

	TED Translators admin edited English subtitles for TEDxUIUC - Christoph Adami - Finding Alien Life
	Ivana Korom edited English subtitles for TEDxUIUC - Christoph Adami - Finding Alien Life
	Ivana Korom edited English subtitles for TEDxUIUC - Christoph Adami - Finding Alien Life

English subtitles

Revisions Compare revisions

Revision 3 Uploaded

TED Translators admin
Revision 2 Edited

Ivana Korom
Revision 1 Uploaded

Ivana Korom

	Revision Number	Author	Created
	3	TED Translators admin
	2	Ivana Korom
	1	Ivana Korom

Finding life we can't imagine | Christoph Adami | TEDxUIUC

Revisions Compare revisions

Our website uses cookies

Operating cookies (Required)