Animations of unseeable biology | Drew Berry | TEDxSydney

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What I'm going to show you
are the astonishing molecular machines
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that create the living
fabric of your body.
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Now molecules are really, really tiny.
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And by tiny, I mean really.
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They're smaller
than a wavelength of light,
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so we have no way
to directly observe them.
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But through science,
we do have a fairly good idea
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of what's going on
down at the molecular scale.
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So what we can do is actually
tell you about the molecules,
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but we don't really have a direct way
of showing you the molecules.
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One way around this is to draw pictures.
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And this idea is actually nothing new.
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Scientists have always created pictures
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as part of their thinking
and discovery process.
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They draw pictures
of what they're observing with their eyes,
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through technology
like telescopes and microscopes,
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and also what they're thinking
about in their minds.
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I picked two well-known examples,
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because they're very well-known
for expressing science through art.
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And I start with Galileo,
who used the world's first telescope
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to look at the Moon.
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And he transformed
our understanding of the Moon.
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The perception in the 17th century
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was the Moon was a perfect
heavenly sphere.
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But what Galileo saw
was a rocky, barren world,
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which he expressed
through his watercolor painting.
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Another scientist with very big ideas,
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the superstar of biology
is Charles Darwin.
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And with this famous entry
in his notebook,
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he begins in the top left-hand
corner with, "I think,"
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and then sketches out
the first tree of life,
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which is his perception
of how all the species,
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all living things on Earth are connected
through evolutionary history --
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the origin of species
through natural selection
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and divergence
from an ancestral population.
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Even as a scientist,
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I used to go to lectures
by molecular biologists
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and find them completely incomprehensible,
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with all the fancy technical
language and jargon
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that they would use
in describing their work,
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until I encountered
the artworks of David Goodsell,
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who is a molecular biologist
at the Scripps Institute.
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And his pictures -- everything's accurate
and it's all to scale.
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And his work illuminated for me
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what the molecular world
inside us is like.
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In the top left-hand corner,
you've got this yellow-green area.
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This is a transection through blood.
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The yellow-green area is the fluid
of blood, which is mostly water,
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but it's also antibodies, sugars,
hormones, that kind of thing.
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And the red region is a slice
into a red blood cell.
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And those red molecules are hemoglobin.
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They are actually red;
that's what gives blood its color.
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And hemoglobin acts as a molecular sponge
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to soak up the oxygen in your lungs
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and then carry it
to other parts of the body.
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I was very much inspired
by this image many years ago,
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and I wondered whether
we could use computer graphics
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to represent the molecular world.
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What would it look like?
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And that's how I really began.
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So let's begin.
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This is DNA in its classic
double helix form.
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And it's from X-ray crystallography,
so it's an accurate model of DNA.
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If we unwind the double helix
and unzip the two strands,
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you see these things that look like teeth.
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Those are the letters of genetic code,
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the 25,000 genes
you've got written in your DNA.
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This is what they typically talk about --
the genetic code --
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this is what they're talking about.
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But I want to talk about
a different aspect of DNA science,
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and that is the physical nature of DNA.
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It's these two strands
that run in opposite directions
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for reasons I can't go into right now.
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But they physically run
in opposite directions,
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which creates a number of complications
for your living cells,
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as you're about to see,
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most particularly
when DNA is being copied.
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And so what I'm about to show you
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is an accurate representation
of the actual DNA replication machine
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that's occurring right now
inside your body,
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at least 2002 biology.
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So DNA's entering the production line
from the left-hand side,
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and it hits this collection,
these miniature biochemical machines,
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that are pulling apart the DNA strand
and making an exact copy.
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So DNA comes in and hits this blue,
doughnut-shaped structure
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and it's ripped apart
into its two strands.
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One strand can be copied directly,
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and you can see these things
spooling off to the bottom there.
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But things aren't so simple
for the other strand
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because it must be copied backwards.
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So it's thrown out
repeatedly in these loops
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and copied one section at a time,
creating two new DNA molecules.
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Now you have billions of this machine
right now working away inside you,
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copying your DNA with exquisite fidelity.
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It's an accurate representation,
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and it's pretty much at the correct speed
for what is occurring inside you.
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I've left out error correction
and a bunch of other things.
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(Laughter)
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This was work from a number of years ago--
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Thank you.
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(Applause)
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This is work from a number of years ago,
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but what I'll show you next
is updated science,
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it's updated technology.
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So again, we begin with DNA.
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And it's jiggling and wiggling there
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because of the surrounding
soup of molecules,
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which I've stripped away
so you can see something.
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DNA is about two nanometers across,
which is really quite tiny.
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But in each one of your cells,
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each strand of DNA is about
30 to 40 million nanometers long.
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So to keep the DNA organized
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and regulate access to the genetic code,
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it's wrapped around these
purple proteins --
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or I've labeled them purple here.
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It's packaged up and bundled up.
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All this field of view
is a single strand of DNA.
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This huge package of DNA
is called a chromosome.
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And we'll come back
to chromosomes in a minute.
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We're pulling out, we're zooming out,
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out through a nuclear pore,
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which is the gateway to this compartment
that holds all the DNA,
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called the nucleus.
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All of this field of view
is about a semester's worth of biology,
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and I've got seven minutes,
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So we're not going to be
able to do that today?
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No, I'm being told, "No."
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This is the way a living cell
looks down a light microscope.
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And it's been filmed under time-lapse,
which is why you can see it moving.
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The nuclear envelope breaks down.
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These sausage-shaped things
are the chromosomes,
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and we'll focus on them.
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They go through this very striking motion
that is focused on these little red spots.
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When the cell feels it's ready to go,
it rips apart the chromosome.
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One set of DNA goes to one side,
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the other side gets
the other set of DNA --
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identical copies of DNA.
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And then the cell splits down the middle.
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And again, you have billions of cells
undergoing this process
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right now inside of you.
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Now we're going to rewind
and just focus on the chromosomes,
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and look at its structure and describe it.
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So again, here we are
at that equator moment.
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The chromosomes line up.
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And if we isolate just one chromosome,
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we're going to pull it out
and have a look at its structure.
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So this is one of the biggest
molecular structures that you have,
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at least as far as we've discovered
so far inside of us.
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So this is a single chromosome.
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And you have two strands of DNA
in each chromosome.
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One is bundled up into one sausage.
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The other strand is bundled up
into the other sausage.
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These things that look like whiskers
that are sticking out from either side
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are the dynamic scaffolding of the cell.
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They're called microtubules,
that name's not important.
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But we're going to focus on
the region labeled red here --
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and it's the interface between
the dynamic scaffolding
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and the chromosomes.
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It is obviously central
to the movement of the chromosomes.
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We have no idea, really,
as to how it's achieving that movement.
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We've been studying this thing
they call the kinetochore
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for over a hundred years
with intense study,
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and we're still just beginning
to discover what it's about.
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It is made up of about
200 different types of proteins,
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thousands of proteins in total.
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It is a signal broadcasting system.
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It broadcasts through chemical signals,
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telling the rest of the cell
when it's ready,
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when it feels that everything
is aligned and ready to go
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for the separation of the chromosomes.
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It is able to couple onto the growing
and shrinking microtubules.
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It's involved with the growing
of the microtubules,
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and it's able to transiently
couple onto them.
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It's also an attention-sensing system.
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It's able to feel when the cell is ready,
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when the chromosome
is correctly positioned.
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It's turning green here because it feels
that everything is just right.
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And you'll see,
there's this one little last bit
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that's still remaining red.
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And it's walked away
down the microtubules.
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That is the signal broadcasting system
sending out the stop signal.
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And it's walked away --
I mean, it's that mechanical.
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It's molecular clockwork.
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This is how you work
at the molecular scale.
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So with a little bit
of molecular eye candy,
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(Laughter)
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we've got kinesins, the orange ones.
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They're little molecular courier
molecules walking one way.
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And here are the dynein,
they're carrying that broadcasting system.
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And they've got their long legs
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so they can step around
obstacles and so on.
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So again, this is all derived
accurately from the science.
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The problem is we can't show it
to you any other way.
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Exploring at the frontier of science,
at the frontier of human understanding,
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is mind-blowing.
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Discovering this stuff
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is certainly a pleasurable
incentive to work in science.
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But most medical researchers --
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discovering the stuff is simply steps
along the path to the big goals,
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which are to eradicate disease,
to eliminate the suffering
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and the misery that disease causes
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and to lift people out of poverty.
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And so with my remaining time,
my four minutes,
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I'm going to introduce you
to one of the most devastating
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and economically important diseases.
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Which inflicts hundreds of millions
of people worldwide every year.
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So again - sound, thank you.
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This parasite is an ancient organism.
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It has been with us
since before we were human.
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Famous victims include
Alexander the Great,
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Ghengis Khan
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and George Washington.
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This is the neck of a sleeping child
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just after the Sun has set.
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And it's feeding time for mosquitoes.
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It's dinner time.
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[The lifecycle of Malaria
Human Host]
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(Sound of mosquito buzzing)
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This mosquito is infected
with a malaria parasite.
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Now, mosquitoes are usually vegetarian,
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they drink honey dew nectar,
fruit juices, that kind of thing.
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Only a pregnant female will bite humans
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seeking nutrients from blood
to nourish her developing eggs.
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During the bite she injects saliva
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to stop the blood from clotting
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and to lubricate the wound.
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Because she is infected with malaria,
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her saliva also contains
the malaria parasite
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so it rides in during the bite.
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The parasite then exits the wound
and seeks out a blood vessel
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and uses the circulatory system
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as a massive freeway
heading for its first target -
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the core of your body's
blood filter system - the liver.
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Within two minutes of the bite,
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the malaria parasites arrive to liver.
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And sensing its arrival then looks
for an exit from the blood stream.
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And this is where malaria
is particularly devious
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because it uses
the very type of immune cell
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that is the resident in the blood stream.
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The immune system is supposed
to remove foreign invaders
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like bacteria and parasites.
11:44 - 11:46

But somehow, we're not quite sure how,
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malaria uses a backdoor entry
into the liver tissue.
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So here's that immune cell.
11:50 - 11:52

Malaria leaves the bloodstream
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and infects a liver cell
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killing one or more liver cells
on its way.
11:56 - 11:58

So again, this is within
a couple of minutes
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of the mosquito bite.
12:00 - 12:02

Once it's infected a liver cell,
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it takes the next five or six days.
12:04 - 12:07

It incubates,
it copies its DNA over and over again
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creating thousands of new parasites.
12:10 - 12:13

So, it's this delay of about a week
since you've had the mosquito bite
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before malaria symptoms start to appear.
12:20 - 12:23

The malaria also transforms
its physical nature;
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it's heading for a new target.
12:30 - 12:33

The next target is your red blood cells.
12:38 - 12:41

Part of its transformation,
the malaria coates itself
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with a coating of molecular hairs
that act like velcro.
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To stick red blood cells
to the outer surface.
12:52 - 12:55

And then they reorient themselves
and penetrate inside the red blood cell.
12:55 - 12:58

This happens within 30 seconds
of leaving the liver.
13:01 - 13:03

This is an aera of intense study -
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if we could stop this process
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we could create a vaccine for malaria.
13:08 - 13:09

Once it's inside the red blood cell
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it can hide
from your body's immune system.
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It then, over the next few days,
13:17 - 13:20

devours the contents of the infected cell
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and creates more parasites.
13:29 - 13:31

It also changes the nature
of the red blood cell
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and makes it sticky
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so it sticks on the blood vessel walls.
13:35 - 13:38

This gives the parasite enough time
to incubate and grow.
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Once it's ready,
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it then bursts out of the red blood cell
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spreading malaria
throughout the bloodstream.
13:49 - 13:51

Malaria victims suffer fever,
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lots of blood, convulsions,
brain damage and coma.
13:55 - 13:58

Countless millions have been killed by it.
13:58 - 14:01

This year between
200 and 300 million people
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will be struct down with malaria.
14:04 - 14:06

Most people who die from the disease
14:06 - 14:09

are pregnant women
and children under the age of five.
14:10 - 14:11

Thank you.
14:11 - 14:16

(Applause)

Title:: Animations of unseeable biology | Drew Berry | TEDxSydney
Description:: We have no ways to directly observe molecules and what they do -- Drew Berry wants to change that. He shows his scientifically accurate (and entertaining!) animations that help researchers see unseeable processes within our own cells.

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:: 14:27

	TED Translators admin edited English subtitles for TEDxSydney - Drew Berry - Astonishing Molecular Machines
	TED Translators admin edited English subtitles for TEDxSydney - Drew Berry - Astonishing Molecular Machines

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