Please double-click on the English subtitles below to play the video.
00:12
Chris Anderson: Mike, welcome.
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It's good to see you.
I'm excited for this conversation.
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Michael Levin: Thank you so much.
I'm so happy to be here.
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CA: So, most of us have
this mental model in biology
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that DNA is a property
of every living thing,
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that it is kind of the software
that builds the hardware of our body.
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That's how a lot of us think about this.
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That model leaves too many deep mysteries.
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Can you share with us
some of those mysteries
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and also what tadpoles have to do with it?
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ML: Sure. Yeah.
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I'd like to give you another
perspective on this problem.
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One of the things that DNA does
is specify the hardware of each cell.
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So the DNA tells every cell
what proteins it's supposed to have.
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And so when you have
tadpoles, for example,
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you see the kind of thing
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that most people think is sort of
a progressive unrolling of the genome.
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Specific genes turn on and off,
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01:09
and a tadpole, as it becomes a frog,
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has to rearrange its face.
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So the eyes, the nostrils, the jaws --
everything has to move.
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01:15
And one way to think about it
used to be that, well,
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you have a sort of hardwired
set of movements
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where all of these things move around
and then you get your frog.
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But actually, a few years ago,
we found a pretty amazing phenomenon,
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which is that if you make
so-called "Picasso frogs" --
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these are tadpoles where the jaws
might be off to the side,
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the eyes are up here,
the nostrils are moved,
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so everything is shifted --
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these tadpoles make
largely normal frog faces.
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Now, this is amazing,
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because all of the organs
start off in abnormal positions,
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and yet they still end up making
a pretty good frog face.
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And so what it turns out
is that this system,
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like many living systems,
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is not a hardwired set of movements,
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but actually works to reduce the error
between what's going on now
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and what it knows is a correct
frog face configuration.
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This kind of decision-making
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that involves flexible responses
to new circumstances,
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in other contexts,
we would call this intelligence.
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And so what we need to understand now
is not only the mechanisms
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by which these cells
execute their movements
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and gene expression and so on,
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but we really have to understand
the information flow:
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How do these cells
cooperate with each other
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to build something large
and to stop building
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when that specific structure is created?
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And these kinds of computations,
not just the mechanisms,
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but the computations
of anatomical control,
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are the future of biology.
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CA: And so I guess the traditional model
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is that somehow cells are sending
biochemical signals to each other
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that allow that development
to happen the smart way.
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But you think there is
something else at work.
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What is that?
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ML: Well, cells certainly do communicate
biochemically and via physical forces,
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but there's something else going on
that's extremely interesting,
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and it's basically called bioelectricity,
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non-neural bioelectricity.
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So it turns out that all cells --
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not just nerves,
but all cells in your body --
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communicate with each other
using electrical signals.
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And what you're seeing here
is a time-lapse video.
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For the first time,
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we are now able to eavesdrop
on all of the electrical conversations
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that the cells are having with each other.
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So think about this.
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We're now watching --
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This is an early frog embryo.
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This is about eight hours
to 10 hours of development.
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And the colors are showing you
actual electrical states
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that allow you to see
all of the electrical software
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that's running on the genome-defined
cellular hardware.
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And so these cells are basically
communicating with each other
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who is going to be head,
who is going to be tail,
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who is going to be left and right
and make eyes and brain and so on.
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And so it is this software
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that allows these living systems
to achieve specific goals,
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goals such as building an embryo
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or regenerating a limb
for animals that do this,
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and the ability to see
these electrical conversations
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gives us some really
remarkable opportunities
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to target or to rewrite
the goals towards which
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these living systems are operating.
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CA: OK, so this is pretty radical.
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Let me see if I understand this.
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What you're saying is that
when an organism starts to develop,
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as soon as a cell divides,
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electrical signals are shared
between them.
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But as you get to, what,
a hundred, a few hundred cells,
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that somehow these signals end up forming
essentially like a computer program,
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a program that somehow includes
all the information needed
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to tell that organism
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what its destiny is?
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Is that the right way to think about it?
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ML: Yes, quite.
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Basically, what happens
is that these cells,
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by forming electrical networks
much like networks in the brain,
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they form electrical networks,
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and these networks process information
including pattern memories.
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They include representation
of large-scale anatomical structures
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where various organs will go,
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what the different axes of the animal --
front and back, head and tail --
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are going to be,
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and these are literally
held in the electrical circuits
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across large tissues
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in the same way that brains
hold other kinds of memories and learning.
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CA: So is this the right way
to think about it?
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Because this seems to be such a big shift.
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I mean, when I first got a computer,
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I was in awe of the people
who could do so-called "machine code,"
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like the direct programming
of individual bits in the computer.
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That was impossible for most mortals.
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To have a chance
of controlling that computer,
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you'd have to program in a language,
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which was a vastly simpler way
of making big-picture things happen.
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And if I understand you right,
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what you're saying is that most of biology
today has sort of taken place
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trying to do the equivalent
of machine code programming,
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of understanding the biochemical signals
between individual cells,
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when, wait a sec, holy crap,
there's this language going on,
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this electrical language,
which, if you could understand that,
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that would give us a completely
different set of insights
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into how organisms are developing.
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Is that metaphor basically right?
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ML: Yeah, this is exactly right.
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So if you think about the way
programming was done in the '40s,
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in order to get your computer
to do something different,
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you would physically
have to shift the wires around.
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So you'd have to go in there
and rewire the hardware.
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You'd have to interact
with the hardware directly,
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and all of your strategies
for manipulating that machine
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would be at the level of the hardware.
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And the reason we have
this now amazing technology revolution,
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information sciences and so on,
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is because computer science moved
from a focus on the hardware
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on to understanding that if
your hardware is good enough --
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and I'm going to tell you that biological
hardware is absolutely good enough --
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then you can interact with your system
not by tweaking or rewiring the hardware,
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but actually, you can take a step back
and give it stimuli or inputs
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the way that you would give
to a reprogrammable computer
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and cause the cellular network
to do something completely different
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than it would otherwise have done.
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So the ability to see
these bioelectrical signals
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is giving us an entry point
directly into the software
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that guides large-scale anatomy,
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which is a very different
approach to medicine
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than to rewiring specific pathways
inside of every cell.
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CA: And so in many ways,
this is the amazingness of your work
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is that you're starting to crack the code
of these electrical signals,
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and you've got an amazing
demonstration of this
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in these flatworms.
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Tell us what's going on here.
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ML: So this is a creature
known as a planarian.
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They're flatworms.
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They're actually quite a complex creature.
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They have a true brain,
lots of different organs and so on.
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And the amazing thing about these planaria
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is that they are highly,
highly regenerative.
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So if you cut it into pieces --
in fact, over 200 pieces --
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every piece will rebuild
exactly what's needed
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to make a perfect little worm.
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So think about that.
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This is a system where every single piece
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knows exactly what
a correct planarian looks like
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and builds the right organs
in the right places and then stops.
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And that's one of the most
amazing things about regeneration.
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So what we discovered is that
if you cut it into three pieces
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and amputate the head and the tail
and you just take this middle fragment,
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which is what you see here,
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amazingly, there is an electrical
gradient, head to tail, that's generated
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that tells the piece
where the heads and the tails go
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and in fact, how many heads or tails
you're supposed to have.
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So what we learned to do
is to manipulate this electrical gradient,
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and the important thing
is that we don't apply electricity.
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What we do instead was we turned
on and off the little transistors --
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they're actual ion channel proteins --
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that every cell natively uses
to set up this electrical state.
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So now we have ways
to turn them on and off,
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and when you do this,
one of the things you can do
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is you can shift that circuit
to a state that says no, build two heads,
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or in fact, build no heads.
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And what you're seeing here are real worms
that have either two or no heads
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that result from this,
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because that electrical map
is what the cells are using
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to decide what to do.
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And so what you're seeing here
are live two-headed worms.
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And, having generated these,
we did a completely crazy experiment.
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You take one of these two-headed worms,
and you chop off both heads,
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and you leave just
the normal middle fragment.
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Now keep in mind, these animals
have not been genomically edited.
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There's absolutely nothing different
about their genomes.
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Their genome sequence
is completely wild type.
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So you amputate the heads,
you've got a nice normal fragment,
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and then you ask: In plain water,
what is it going to do?
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And, of course, the standard
paradigm would say,
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well, if you've gotten rid
of this ectopic extra tissue,
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the genome is not edited so it should
make a perfectly normal worm.
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And the amazing thing is
that it is not what happens.
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These worms, when cut again and again,
in the future, in plain water,
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they continue to regenerate as two-headed.
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Think about this.
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The pattern memory to which these animals
will regenerate after damage
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has been permanently rewritten.
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And in fact, we can now write it back
and send them back to being one-headed
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without any genomic editing.
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So this right here is telling you
that the information structure
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that tells these worms how many heads
they're supposed to have
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is not directly in the genome.
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It is in this additional
bioelectric layer.
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Probably many other things are as well.
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And we now have the ability to rewrite it.
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And that, of course,
is the key definition of memory.
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It has to be stable, long-term stable,
and it has to be rewritable.
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And we are now beginning to crack
this morphogenetic code
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to ask how is it that these tissues
store a map of what to do
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and how we can go in
and rewrite that map to new outcomes.
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CA: I mean, that seems
incredibly compelling evidence
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that DNA is just not
controlling the actual final shape
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of these organisms,
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that there's this
whole other thing going on,
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and, boy, if you could crack that code,
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what else could that lead to.
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By the way, just looking at these ones.
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What is life like
for a two-headed flatworm?
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I mean, it seems like
it's kind of a trade-off.
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The good news is you have this amazing
three-dimensional view of the world,
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but the bad news is you have
to poop through both of your mouths?
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ML: So, the worms have
these little tubes called pharynxes,
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and the tubes are sort of
in the middle of the body,
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and they excrete through that.
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These animals are perfectly viable.
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They're completely happy, I think.
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The problem, however,
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is that the two heads
don't cooperate all that well,
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and so they don't really eat very well.
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But if you manage to feed them by hand,
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they will go on forever,
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and in fact, you should know
these worms are basically immortal.
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So these worms, because
they are so highly regenerative,
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they have no age limit,
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and they're telling us that
if we crack this secret of regeneration,
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which is not only growing new cells
but knowing when to stop --
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you see, this is absolutely crucial --
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if you can continue to exert
this really profound control
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over the three-dimensional structures
that the cells are working towards,
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you could defeat aging
as well as traumatic injury
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and things like this.
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So one thing to keep in mind
is that this ability to rewrite
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the large-scale anatomical
structure of the body
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is not just a weird planarian trick.
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It's not just something
that works in flatworms.
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What you're seeing here is a tadpole
with an eye and a gut,
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and what we've done is turned on
a very specific ion channel.
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So we basically just manipulated
these little electrical transistors
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that are inside of cells,
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and we've imposed a state
on some of these gut cells
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that's normally associated
with building an eye.
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And as a result, what the cells do
is they build an eye.
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These eyes are complete.
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They have optic nerve, lens, retina,
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all the same stuff that an eye
is supposed to have.
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They can see, by the way,
out of these eyes.
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And what you're seeing here
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is that by triggering
eye-building subroutines
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in the physiological software of the body,
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you can very easily tell it
to build a complex organ.
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And this is important for our biomedicine,
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because we don't know how to micromanage
the construction of an eye.
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I think it's going to be
a really long time
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13:12
before we can really bottom-up build
things like eyes or hands and so on.
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But we don't need to, because the body
already knows how to do it,
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and there are these subroutines
that can be triggered
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by specific electrical patterns
that we can find.
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And this is what we call
"cracking the bioelectric code."
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13:29
We can make eyes. We can make extra limbs.
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13:31
Here's one of our five-legged tadpoles.
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We can make extra hearts.
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We're starting to crack the code
to understand where are the subroutines
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in this software
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that we can trigger
and build these complex organs
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long before we actually know
how to micromanage the process
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at the cellular level.
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CA: So as you've started to get
to learn this electrical layer
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and what it can do,
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you've been able to create --
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is it fair to say it's almost
like a new, a novel life-form,
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called a xenobot?
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Talk to me about xenobots.
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ML: Right.
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So if you think about this,
this leads to a really strange prediction.
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If the cells are really willing to build
towards a specific map,
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we could take genetically unaltered cells,
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14:16
and what you're seeing here
is cells taken out of a frog body.
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14:19
They've coalesced in a way that asks them
to re-envision their multicellularity.
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14:24
And what you see here
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is that when liberated from the rest
of the body of the animal,
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they make these tiny little novel bodies
that are, in terms of behavior,
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you can see they can move,
they can run a maze.
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14:35
They are completely different
from frogs or tadpoles.
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14:38
Frog cells, when asked to re-envision
what kind of body they want to make,
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14:44
do something incredibly interesting.
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14:46
They use the hardware
that their genetics gives them,
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14:51
for example, these
little hairs, these little cilia
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14:54
that are normally used to redistribute
mucus on the outside of a frog,
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14:58
those are genetically specified.
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14:59
But what these creatures did,
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15:02
because the cells are able
to form novel kinds of bodies,
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15:06
they have figured out
how to use these little cilia
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15:09
to instead row against the water,
and now have locomotion.
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15:13
So not only can they move around,
but they can, and here what you're seeing,
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15:18
is that these cells
are coalescing together.
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15:21
Now they're starting to have conversations
about what they are going to do.
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15:24
You can see here the flashes
are these exchanges of information.
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15:28
Keep in mind, this is just skin.
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15:30
There is no nervous system.
There is no brain. This is just skin.
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15:34
This is skin that has learned
to make a new body
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15:37
and to explore its environment
and move around.
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15:40
And they have spontaneous behaviors.
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15:42
You can see here where
it's swimming down this maze.
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2479
15:45
At this point, it decides to turn around
and go back where it came from.
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15:48
So it has its own behavior,
and this is a remarkable model system
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3529
15:52
for several reasons.
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15:53
First of all, it shows us
the amazing plasticity of cells
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15:57
that are genetically wild type.
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15:58
There is no genetic editing here.
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16:00
These are cells that are really prone
to making some sort of functional body.
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5129
16:05
The second thing,
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1151
16:06
and this was done in collaboration
with Josh Bongard's lab at UVM,
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3313
16:10
they modeled the structure of these things
and evolved it in a virtual world.
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16:16
So this is literally -- on a computer,
they modeled it on a computer.
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3279
16:19
So this is literally the only organism
that I know of on the face of this planet
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4052
16:23
whose evolution took place
not in the biosphere of the earth
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3159
16:27
but inside a computer.
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1910
16:29
So the individual cells
have an evolutionary history,
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2688
16:31
but this organism
has never existed before.
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2444
16:34
It was evolved in this virtual world,
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16:36
and then we went ahead
and made it in the lab,
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2636
16:39
and you can see this amazing plasticity.
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2504
16:41
This is not only
for making useful machines.
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3211
16:45
You can imagine now programming these
to go out into the environment
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3989
16:49
and collect toxins and cleanup,
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1656
16:50
or you could imagine ones
made out of human cells
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2493
16:53
that would go through your body
and collect cancer cells
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2995
16:56
or reshape arthritic joints,
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2425
16:58
deliver pro-regenerative compounds,
346
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2369
17:01
all kinds of things.
347
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1151
17:02
But not only these useful applications --
this is an amazing sandbox
348
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3475
17:05
for learning to communicate
morphogenetic signals to cell collectives.
349
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4602
17:10
So once we crack this, once we understand
how these cells decide what to do,
350
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4906
17:15
and then we're going to, of course,
learn to rewrite that information,
351
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3349
17:18
the next steps are great improvements
in regenerative medicine,
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4831
17:23
because we will then be able
to tell cells to build healthy organs.
353
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3737
17:27
And so this is now
a really critical opportunity
354
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3261
17:30
to learn to communicate with cell groups,
355
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2097
17:32
not to micromanage them,
not to force the hardware,
356
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2539
17:35
to communicate and rewrite the goals
that these cells are trying to accomplish.
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4150
17:40
CA: Well, it's mind-boggling stuff.
358
1060026
1982
17:42
Finally, Mike, give us
just one other story
359
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3158
17:45
about medicine that might be to come
360
1065214
3111
17:48
as you develop this understanding
361
1068349
3096
17:51
of how this bioelectric layer works.
362
1071469
2764
17:54
ML: Yeah, this is incredibly exciting
because, if you think about it,
363
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3394
17:58
most of the problems of biomedicine --
364
1078236
1889
18:00
birth defects, degenerative disease,
aging, traumatic injury, even cancer --
365
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6066
18:06
all boil down to one thing:
366
1086239
1714
18:07
cells are not building
what you would like them to build.
367
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2910
18:10
And so if we understood
how to communicate with these collectives
368
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3456
18:14
and really rewrite
their target morphologies,
369
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4567
18:18
we would be able to normalize tumors,
370
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2192
18:21
we would be able to repair birth defects,
371
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1969
18:23
induce regeneration of limbs
and other organs,
372
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2584
18:25
and these are things
we have already done in frog models.
373
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3392
18:29
And so now the next really exciting step
374
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2662
18:31
is to take this into mammalian cells
375
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3729
18:35
and to really turn this into the next
generation of regenerative medicine
376
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3486
18:39
where we learn to address
all of these biomedical needs
377
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4521
18:43
by communicating with the cell collectives
378
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2080
18:45
and rewriting their bioelectric
pattern memories.
379
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3438
18:49
And the final thing I'd like to say
is that the importance of this field
380
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3562
18:52
is not only for biomedicine.
381
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1658
18:54
You see, this, as I started out by saying,
382
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2163
18:56
this ability of cells
in novel environments
383
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2612
18:59
to build all kinds of things
besides what their genome tells them
384
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3944
19:03
is an example of intelligence,
385
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1857
19:05
and biology has been
intelligently solving problems
386
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2657
19:07
long before brains came on the scene.
387
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1928
19:09
And so this is also the beginnings
of a new inspiration for machine learning
388
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4849
19:14
that mimics the artificial intelligence
of body cells, not just brains,
389
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4339
19:19
for applications in computer intelligence.
390
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3220
19:24
CA: Mike Levin, thank you
for your extraordinary work
391
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3139
19:27
and for sharing it
so compellingly with us.
392
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2303
19:30
Thank you.
393
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1151
19:31
ML: Thank you so much. Thank you, Chris.
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1999
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